1 Introduction
This paper deals with the mod p geometry and arithmetic of some Shimura varieties at ramified places. More precisely, we study the reduction modulo p of the splitting models for PEL-type Shimura varieties constructed by Pappas-Rapoport in [Reference Pappas and Rapoport49]. For smooth splitting models, we explore the mod p Hodge structures on their special fibers by constructing universal F-zips with additional structure of fixed type (determined by the Hodge cocharacter). Then we derive some consequences for the geometry and coherent cohomology. In particular, we reprove the main results of Bijakowski-Hernandez [Reference Bijakowski and Hernandez6] by different methods. We also clarify and generalize the work of Reduzzi-Xiao [Reference Reduzzi and Xiao56] in the ramified Hilbert case.
PEL moduli spaces are central objects to study in arithmetic geometry and the Langlands program. If the associated reductive group is unramified at p, Kottwitz constructed smooth integral PEL moduli spaces in [Reference Kottwitz30]. In the general setting, Rapoport and Zink in [Reference Rapoport55] introduced similar and generalized integral PEL moduli spaces
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
. These are called naive integral models, as shown by Pappas in [Reference Pappas45] that in some ramified unitary case, the moduli scheme
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
fails to be flat over
${\mathcal {O}}_E$
, the ring of integers of the local reflex field E. To study integral models of PEL-type Shimura varieties in the ramified case, in [Reference Pappas and Rapoport49] Pappas and Rapoport introduced the so-called splitting integral models
${\mathscr {A}}^{\mathrm {spl}}$
. Roughly speaking, in the setting of [Reference Pappas and Rapoport49], the associated p-adic reductive group G has the form of a Weil restriction and the ramification comes mainly from restriction of scalars. After fixing the data, the model
${\mathscr {A}}^{\mathrm {spl}}$
is proposed as a relative moduli space over the naive integral model
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
, the latter constructed in [Reference Rapoport55]. For any scheme S over
${\mathcal {O}}_E$
,
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}(S)$
classifies abelian schemes with PEL structure
$\underline {A}=(A,\lambda , \iota ,\alpha )$
over S. Fix a sufficiently large field extension
$F|E$
. For a scheme S over
${\mathcal {O}}_F$
,
${\mathscr {A}}^{\mathrm {spl}}(S)$
classifies
$(\underline {A}, \underline {\mathscr {F}_{\bullet }})$
, where
$\underline {A}\in {\mathscr {A}}^{\operatorname {\mathrm {naive}}}(S)$
and
$\underline {\mathscr {F}_{\bullet }}$
is a filtration on the cotangent bundle
$\omega _{A/S}$
, satisfying certain conditions related to the ramification data. Pappas and Rapoport proved that the model
${\mathscr {A}}^{\mathrm {spl}}$
over
${\mathcal {O}}_F$
admits nice properties. In particular, there is a scheme
$\mathbb {M}^{\mathrm {spl}}$
(called the splitting local model) over
${\mathcal {O}}_F$
, so that
${\mathscr {A}}^{\mathrm {spl}}$
and
$\mathbb {M}^{\mathrm {spl}}$
sit in a local model diagram. Moreover, by construction
$\mathbb {M}^{\mathrm {spl}}$
can be realized as a twisted product of unramified local models. There is a natural morphism
${\mathscr {A}}^{\mathrm {spl}}\rightarrow {\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
, which is the composition of the forgetful morphism
${\mathscr {A}}^{\mathrm {spl}}\rightarrow {\mathscr {A}}^{\operatorname {\mathrm {naive}}}_{{\mathcal {O}}_F}$
over
${\mathcal {O}}_F$
and the base change projection map
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}_{{\mathcal {O}}_F}\rightarrow {\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
. Pappas and Rapoport defined the canonical model
${\mathscr {A}}$
as the scheme-theoretic image of this morphism. Then
${\mathscr {A}}$
is a flat integral model over
${\mathcal {O}}_E$
. In case that the group G is tamely ramified and
$p\nmid |\pi _1(G_{der})|$
, then up to the Hasse principle the scheme
${\mathscr {A}}$
should coincide with the Kisin-Pappas integral models [Reference Kisin and Pappas28]. We refer to [Reference Pappas and Rapoport49] for more information and details on the general theory of splitting models (so far only available in the PEL-type case) and to [Reference Pappas46, Reference Pappas47, Reference Pappas and Rapoport51] for some recent progress on the canonical models.
The most well-known splitting models come from the example of Hilbert modular varieties. In this case,
${\mathscr {A}}={\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
and the special fiber of
${\mathscr {A}}$
was previously studied by Deligne and Pappas in [Reference Deligne and Pappas13]. Let L be a totally real field of degree
$g>1$
and p a prime number. Let
$\kappa |\mathbb {F}_p$
be a large enough finite field and
$\mathcal {M}^{\textrm {DP}}={\mathscr {A}}\otimes \kappa $
the Deligne-Pappas moduli space over
$\kappa $
, which parameterizes abelian schemes with real multiplication given by
${\mathcal {O}}_L$
together with polarization and level structure. If p is unramified in L, this is a smooth scheme (a special case of the Kottwitz models [Reference Kottwitz30]). Here we are mainly concerned with the case where p ramifies in L. Then
$\mathcal {M}^{\textrm {DP}}$
is only a normal scheme that is singular (cf. [Reference Deligne and Pappas13]). By contrast, the special fiber of
${\mathscr {A}}^{\mathrm {spl}}$
over
$\kappa $
, in this case denoted by
$\mathcal {M}^{\textrm {PR}}$
, is smooth and the natural morphism
$$\begin{align*}\mathcal{M}^{\textrm{PR}}\rightarrow \mathcal{M}^{\textrm{DP}}\end{align*}$$
is a resolution of singularities. In [Reference Reduzzi and Xiao56] Reduzzi and Xiao constructed g partial Hasse invariants on
$\mathcal {M}^{\textrm {PR}}$
by carefully exploring the structure of Pappas-Rapoport filtrations. On the other hand, in the ramified case the number of partial Hasse invariants on
$\mathcal {M}^{\textrm {DP}}$
is strictly less than g (see the introduction of [Reference Reduzzi and Xiao56] and the references therein). Reduzzi and Xiao applied these g partial Hasse invariants to
$\mathcal {M}^{\textrm {PR}}$
to construct Galois pseudorepresentations attached to torsion Hecke eigenclasses in the coherent cohomology. This shows a big advantage to work with splitting models. The space
$\mathcal {M}^{\textrm {PR}}$
and the partial Hasse invariants on it have been serving as a basic tool in the study of geometry and arithmetic of Hilbert modular varieties, for example, see the recent works of Sasaki [Reference Sasaki58] and Diamond-Kassaei [Reference Diamond and Kassaei14].
In the more general PEL setting, recently Bijakowski and Hernandez in [Reference Bijakowski and Hernandez6] studied some aspects of the mod p geometry of splitting models. More precisely, they proved that
${\mathscr {A}}^{\mathrm {spl}}$
with maximal level at p is smooth under some conditions on the PEL datum. Roughly, these conditions are to ensure that at a p-adic place
$v_i$
, the group has the form
$\operatorname {\mathrm {Res}}_{F_i|{\mathbb {Q}}_p}H_i$
, where
$H_i$
is unramified over
$F_i$
, and the level at p is hyperspecial for these
$H_i$
. In particular, this excludes the ramified unitary groups (labeled as type (AR) in [Reference Bijakowski and Hernandez6]) as local factors. Bijakowski and Hernandez also proved that the
$\mu $
-ordinary locus (defined as the maximal Newton stratum) is open and dense in the special fiber
${\mathscr {A}}^{\mathrm {spl}}_0$
of
${\mathscr {A}}^{\mathrm {spl}}$
. For this, they introduced a so-called Hodge stratification and proved that the maximal Hodge stratum (which contains the
$\mu $
-ordinary locus) is open and dense.
In this paper, we essentially work in the same setting as that in [Reference Bijakowski and Hernandez6]. Our first key observation is that one can modify the local model diagram between
${\mathscr {A}}^{\mathrm {spl}}$
and
$\mathbb {M}^{\mathrm {spl}}$
constructed in [Reference Pappas and Rapoport49] to a local model diagram between
${\mathscr {A}}^{\mathrm {spl}}$
and
$\prod _{i,j.l}\mathbb {M}^{\mathrm {loc}}(\mathcal {G}_{i,j}^l,\mu _{i,j}^l)$
, a product of unramified local models related to the PEL datum, cf. Proposition A.8. This is not quite surprising, as we already mentioned above that the splitting local model
$\mathbb {M}^{\mathrm {spl}}=\mathbb {M}^{\mathrm {spl}}(\mathcal {G},\mu )$
was constructed in [Reference Pappas and Rapoport49] as a twisted product of unramified local models
$\mathbb {M}^{\mathrm {loc}}(\mathcal {G}_{i,j}^l,\mu _{i,j}^l)$
. Let G be the reductive group defined by the PEL datum, which we assume to be connected (thus we exclude the type D case), and
$\{\mu \}$
the attached geometric conjugacy class of Hodge cocharacters of G. In the following we often fix a suitable choice of
$\mu $
in this conjugacy class. Recall that
$E|\mathbb {Q}_p$
is the field of definition of
$\{\mu \}$
and
$F|E$
is a large enough extension (so that G splits over F). The group scheme related to the modified local model diagram is
$\mathcal {G}^{\mathrm {spl}}$
, a reductive group over
${\mathcal {O}}_F$
, which is the reductive model of the split group
$G_F$
. On the other hand, let
$\mathcal {G}$
be the parahoric model of G over
$\mathbb {Z}_p$
associated to the integral PEL datum. The local model diagram of [Reference Pappas and Rapoport49] corresponds to a morphism of algebraic stacks
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}}\rightarrow [\mathbb{M}^{\mathrm{spl}}(\mathcal{G},\mu)/\mathcal{G}_{{\mathcal{O}}_F}],\end{align*}$$
which is more suited to study the canonical model
${\mathscr {A}}$
and its related canonical local model. On the other hand, the local model diagram here corresponds to a morphism
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}}\rightarrow [\mathbb{M}^{\mathrm{loc}}(\mathcal{G}^{\mathrm{spl}},\mu)/\mathcal{G}^{\mathrm{spl}}],\end{align*}$$
where
$ \mathbb {M}^{\mathrm {loc}}(\mathcal {G}^{\mathrm {spl}},\mu )=\prod _{i,j,l}\mathbb {M}^{\mathrm {loc}}(\mathcal {G}_{i,j}^l,\mu _{i,j}^l).$
If there is an i such that the finite extension
$F_i|\mathbb {Q}_p$
is ramified, then in general
$$\begin{align*}\mathcal{G}_{{\mathcal{O}}_F}\neq \mathcal{G}^{\mathrm{spl}}.\end{align*}$$
From the modified diagram here, we can immediately deduce the smoothness of
${\mathscr {A}}^{\mathrm {spl}}$
if the local factors
$\mathcal {G}_i$
satisfy the same condition as that in [Reference Bijakowski and Hernandez6] (compare [Reference Bijakowski and Hernandez6] Theorem 2.30 and Remark 2.31). Under this condition, the parahoric subgroup
$K_p=\mathcal {G}(\mathbb {Z}_p)$
is in fact very special in the sense of [Reference Zhu71].
In fact, the above observation on the modified local model diagram leads us to go much further. Recall that the theory of F-zips was introduced and studied by Moonen-Wedhorn in [Reference Moonen and Wedhorn43] as a candidate for a mod p Hodge structure. This notion has been promoted and enlarged by Fontaine-Jannsen [Reference Fontaine and Jannsen17], Drinfeld [Reference Drinfeld15], and Bhatt-Lurie [Reference Bhatt9]. Here we work with the generalization of F-zips in another direction: the notion of G-zips for a reductive group G over a finite field, cf. [Reference Pink, Wedhorn and Ziegler53, Reference Pink, Wedhorn and Ziegler54]. Back to splitting models of PEL-type Shimura varieties, we will work with smooth splitting models
${\mathscr {A}}^{\mathrm {spl}}$
from now on (in particular, this excludes the ramified unitary group case). Let
$\kappa $
be the residue field of
${\mathcal {O}}_F$
and
${\mathscr {A}}^{\mathrm {spl}}_0$
the special fiber of
${\mathscr {A}}^{\mathrm {spl}}$
over
$\kappa $
.
Theorem 1.1 (Theorem 3.13).
-
(1) There is a natural
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of type
$\mu $
over
${\mathscr {A}}^{\mathrm {spl}}_0$
, where
$\mathcal {G}^{\mathrm {spl}}_0$
is a reductive group over
${\mathbb {F}}_p$
constructed from the PEL datum such that
$\mathcal {G}^{\mathrm {spl}}_{0,\kappa }=\mathcal {G}^{\mathrm {spl}}\otimes _{{\mathcal {O}}_F}\kappa $
. -
(2) The induced map to the moduli stack of
$\mathcal {G}^{\mathrm {spl}}_0$
-zips of type
$\mu $
is smooth and surjective.
$$\begin{align*}\zeta: {\mathscr{A}}^{\mathrm{spl}}_0\rightarrow \mathcal{G}^{\mathrm{spl}}_0\textrm{-}\mathrm{Zip}^\mu_{\kappa}\end{align*}$$
Let us first comment on the related reductive groups appearing here. For
${\mathscr {A}}^{\mathrm {spl}}_0$
, the group
$\mathcal {G}^{\mathrm {spl}}_0$
replaces
$\mathcal {G}_0^{\textrm {rdt}}$
, the maximal reductive quotient of the special fiber
$\mathcal {G}_0$
of
$\mathcal {G}$
. The group
$\mathcal {G}_0^{\textrm {rdt}}$
is mainly related to the geometry of
${\mathscr {A}}_0$
, the special fiber of the canonical model
${\mathscr {A}}$
. Recall that there is a natural morphism
${\mathscr {A}}^{\mathrm {spl}}_0\rightarrow {\mathscr {A}}_0$
. The difference between
$\mathcal {G}^{\mathrm {spl}}_0$
and
$\mathcal {G}_0^{\textrm {rdt}}$
reflects the ramification data. Indeed, at a p-adic place
$v_i$
, the local factors of the two groups admit the following description:
$$\begin{align*}\mathcal{G}^{\mathrm{spl}}_{0,i}=\operatorname{\mathrm{Res}}_{\kappa_i|{\mathbb{F}}_p}H_i^{e_i},\quad \mathcal{G}_{0,i}^{\textrm{rdt}}= \operatorname{\mathrm{Res}}_{\kappa_i|{\mathbb{F}}_p}H_i,\end{align*}$$
where
$\kappa _i$
is the residue field of
$F_i$
,
$e_i$
is the ramification index of the extension
$F_i|\mathbb {Q}_p$
, and
$H_i$
is a reductive group over
$\kappa _i$
. Note that the Hodge cocharacter
$\mu $
of G over F naturally admits a reduction to a cocharacter of
$\mathcal {G}^{\mathrm {spl}}_0$
over
$\kappa $
.
Now we briefly explain the construction of the universal
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of type
$\mu $
. In the unramified PEL case, we have
${\mathscr {A}}_0={\mathscr {A}}^{\operatorname {\mathrm {naive}}}_0={\mathscr {A}}^{\mathrm {spl}}_0$
and the construction is direct, cf. [Reference Moonen and Wedhorn43, Reference Viehmann and Wedhorn65] and [Reference Zhang70]. However, in the ramified case, the construction becomes rather indirect and complicated. Since a general PEL datum is involved, we illustrate the ideas by working with the example of Hilbert-Siegel case. For the general case, see sections 2 and 3. Then the PEL datum
$(B, \ast , V, \left \langle \cdot , \cdot \right \rangle , {\mathcal {O}}_B,\Lambda )$
is of type C and
$B=L$
is a totally real field, which we assume
$[L:\mathbb {Q}]>1$
. We further assume that there is only one finite place v of L over p and the local field
$F_1:=L_v$
is ramified over
$\mathbb {Q}_p$
, i.e., the ramification index
$e=[F_1:F_1^{\textrm {ur}}]>1$
, where
$F_1^{\textrm {ur}}$
is the maximal unramified subextension of
$F_1$
over
$\mathbb {Q}_p$
. Let
$f=[F_1^{\textrm {ur}}:\mathbb {Q}_p]=[\kappa _1:\mathbb {F}_p]$
, where
$\kappa _1$
is the residue field of
$F_1$
, so that
$[F_1:\mathbb {Q}_p]=ef$
. Let
$K^p\subset G(\mathbb {A}_f^p)$
be a fixed sufficiently small open compact subgroup. Recall
$F|F_1$
is a fixed large enough extension with residue field
$\kappa $
. For any
$\kappa $
-scheme S, let
$\underline {A}=(A, \lambda , \iota , \alpha )$
be an S-point of
$\mathscr {A}^{\operatorname {\mathrm {naive}}}=\mathscr {A}^{\operatorname {\mathrm {naive}}}_{K^p}$
. Then we have an exact sequence of locally free sheaves of
${\mathcal {O}}_S$
-modules
$$\begin{align*}0 \to \omega_{A/S} \to H_{\operatorname{\mathrm{dR}}}^1(A/S) \to \operatorname{\mathrm{Lie}}_{A^\vee/S} \to 0.\end{align*}$$
In the unramified case, this exact sequence, together with the Frobenius and Verschiebung morphisms, defines the F-zip with additional structure of type
$\mu $
over
${\mathscr {A}}^{\mathrm {spl}}_0$
. However, in our ramified case here, it turns out a posteriori that the type of the Hodge filtrations constructed in this way will vary, which reflects the singularities of
${\mathscr {A}}_0$
in some sense.
Indeed, we have the Kottwitz-Rapoport stratification on
${\mathscr {A}}_0$
(see later), and on each stratum by [Reference Shen, Yu and Zhang59] we have a
$\mathcal {G}_0^{\textrm {rdt}}$
-zip of a certain type (dependent on this stratum). Recall the natural map
${\mathscr {A}}_0^{\mathrm {spl}}\rightarrow {\mathscr {A}}_0$
. We can pullback these
$\mathcal {G}_0^{\textrm {rdt}}$
-zips to the corresponding preimages of KR strata in
${\mathscr {A}}_0^{\mathrm {spl}}$
. But these do not give the correct object that we want. Here, to construct the
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of fixed type
$\mu $
over
${\mathscr {A}}^{\mathrm {spl}}_0$
, we have to take into account the splitting structures. It is here that our modified local model diagram (over
$\kappa $
)
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}}_0\rightarrow [\mathbb{M}^{\mathrm{loc}}(\mathcal{G}^{\mathrm{spl}},\mu)_0/\mathcal{G}^{\mathrm{spl}}_{\kappa}]\end{align*}$$
plays the key role. Under our smoothness assumption, the underlying topological space of
$[\mathbb {M}^{\mathrm {loc}}(\mathcal {G}^{\mathrm {spl}},\mu )_0/\mathcal {G}^{\mathrm {spl}}_{\kappa }]$
has only one point. Then the construction is guided by the constructions in [Reference Shen, Yu and Zhang59] subsections 3.3 and 3.4. On the other hand, we remark that it is very hard to work with the original local model diagram
${\mathscr {A}}^{\mathrm {spl}}_0\rightarrow [\mathbb {M}^{\mathrm {spl}}(\mathcal {G},\mu )_0/\mathcal {G}_{\kappa }]$
of [Reference Pappas and Rapoport49]. The quotient stack
$[\mathbb {M}^{\mathrm {spl}}(\mathcal {G},\mu )_0/\mathcal {G}_{\kappa }]$
is quite complicated, and in fact it is not known whether the set of
${\mathcal {G}}_\kappa $
-orbits on
$\mathbb {M}^{\mathrm {spl}}(\mathcal {G},\mu )_0$
is finite or not in general (cf. [Reference Berger3] section 8 and [Reference Berger4]).
Let us discuss in more detail the construction of the
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of fixed type
$\mu $
over
${\mathscr {A}}^{\mathrm {spl}}_0$
. Let
$(\underline {A}, \underline {\mathscr {F}_{\bullet }})$
be an S-valued point of
${\mathscr {A}_0}^{\mathrm {spl}}$
. Then by definition
$\underline {A}=(A, \lambda , \iota ,\alpha )\in \mathscr {A}^{\operatorname {\mathrm {naive}}}(S)$
,
$\underline {\mathscr {F}_{\bullet }}=\{\mathscr {F}_{j}^l\}$
is a Pappas-Rapoport filtration of the
${\mathcal {O}}_{F_1} \otimes _{\mathbb {Z}_p} {\mathcal {O}}_S$
-module
$\omega _{A/S}$
. To explain this term, we write
$\mathcal {H} =H_{\operatorname {\mathrm {dR}}}^1(A/S)$
, which is an
${\mathcal {O}}_{F_1^{\textrm {ur}}} \otimes _{\mathbb {Z}_p} {\mathcal {O}}_S$
-module, hence it has a decomposition
$$\begin{align*}\mathcal{H} = \bigoplus_{j} \mathcal{H}_{j},\end{align*}$$
where
$\mathcal {H}_{j}$
is the locally free sub
${\mathcal {O}}_S$
-module of
$\mathcal {H}$
, where
${\mathcal {O}}_{F_1^{\textrm {ur}}}$
acts by the fixed embedding
$\sigma _j: {\mathcal {O}}_{F_1^{\textrm {ur}}}\rightarrow {\mathcal {O}}_F$
. For each j, there is a pairing on
$\mathcal {H}_j$
induced from the pairing on
$\mathcal {H}$
coming from the polarization
$\lambda $
. Similarly, we have a decomposition
$\omega _{A/S}=\bigoplus _j\omega _j$
with
$\omega _j\subset \mathcal {H}_j$
for each
$1\leq j\leq f$
. The Pappas-Rapoport filtration is by definition a filtration of locally direct
${\mathcal {O}}_S$
-factors of each
$\omega _{j}$
.
$$\begin{align*}0 = \mathscr{F}_{j}^0 \subset \mathscr{F}_{j}^1 \subset \cdots \subset \mathscr{F}_{j}^{e} = {\omega_{j}} \subset \mathcal{H}_{j}\end{align*}$$
with
${\mathcal {O}}_{F_1}/ (p) \simeq \kappa _1[T]/(T^{e}) = \kappa _1[\varepsilon _1]$
action, such that
$\kappa _1$
acts on
$\mathscr {F}_{j}^l$
by
$\sigma _{j}: \mathcal {O}_{F_1^{\mathrm {ur}}} \to \kappa $
; for all
$1 \leq l \leq e$
,
$\mathscr {F}_{j}^l / \mathscr {F}_{j}^{l-1}$
is locally free of rank
$d_{j}^l$
and
$\varepsilon _1 \mathscr {F}_{j}^l \subset \mathscr {F}_{j}^{l-1}$
.
The
${\mathcal {O}}_{F_1^{\textrm {ur}}}$
-action on
$\Lambda $
induces a decomposition
$\Lambda =\bigoplus _{j}\Lambda _j$
. For each embedding
$\sigma ^l_j: {\mathcal {O}}_{F_1}\hookrightarrow {\mathcal {O}}_F$
which extends
$\sigma _j: {\mathcal {O}}_{F_1^{\textrm {ur}}}\hookrightarrow {\mathcal {O}}_F$
, we set
$\Lambda _j^l=\Lambda _j\otimes _{{\mathcal {O}}_{F_1},\sigma ^l_j}{\mathcal {O}}_F$
(note that the lattice
$\Lambda _{j}^l$
is denoted by
$\Xi _{j}^l$
in [Reference Pappas and Rapoport49, Proposition 5.2]) and
$\Lambda ^l=\bigoplus _j\Lambda _j^l$
. Set
$ \Lambda _{j,0}^l=\Lambda _j^l\otimes _{{\mathcal {O}}_F}\kappa $
and
$\Lambda ^{\mathrm {spl}}_0=\bigoplus _l\bigoplus _j\Lambda _{j,0}^l$
. One can show that there is a standard F-zip structure on
$\Lambda ^{\mathrm {spl}}_0$
, whose Hodge filtration is given by the cocharacter
$\mu $
over
$\kappa $
.
For
$S={\mathscr {A}_0}^{\mathrm {spl}}$
and
$(\underline {{A}}, \underline {\mathscr {F}_{\bullet }}) \in {\mathscr {A}_0}^{\mathrm {spl}}(S)$
the universal object, one can associate a module
$$\begin{align*}\mathcal{M}:= \bigoplus_{ l=1}^e \bigoplus_{ j=1}^f \mathcal{M}_{j}^l, \quad\text{ with }\quad\mathcal{M}_{j}^l := \varepsilon_1^{-1}\mathscr{F}_{j}^{l-1} / \mathscr{F}_{j}^{l-1}.\end{align*}$$
Then each
$\mathcal {M}_{j}^l$
is a locally free
${\mathcal {O}}_S$
-module, and locally isomorphic to
$\Lambda _{j}^l \otimes _{{\mathcal {O}}_F} {\mathcal {O}}_S$
, cf. [Reference Pappas and Rapoport49]. Now the idea is to transfer the Hodge and conjugate filtrations on
$\mathcal {H}$
to filtrations on each
$\mathcal {M}^l:=\bigoplus _j\mathcal {M}_{j}^l$
, and to show that the F-zip structure on
$\mathcal {H}$
induces an F-zip structure on
$\mathcal {M}$
. To this end, one can first complete the filtration of
$\omega $
to a full filtration of
$\mathcal {H}$
, then apply the Frobenius and Verschiebung morphisms successively to the full filtration, and make use of the usual relation
$\textrm {Ker}\, F=\textrm {Im}\, V, \textrm {Ker}\, V=\textrm {Im}\, F$
to succeed. In fact, we proceed by an alternative and equivalent approach. For any
$1\leq j \leq f$
, inspired by [Reference Reduzzi and Xiao56] we construct explicit linear maps
$F_{j}^l: \mathcal {M}_{j}^{l-1} \to \mathcal {M}_{j}^{l},\; V_{j}^l: \mathcal {M}_{j}^l \to \mathcal {M}_{j}^{l-1}$
for each
$2 \leq l \leq e$
(which are easy to construct), and
$\sigma ^{-1}$
-linear (
$\sigma $
-linear) maps
$F_{j}^1: \mathcal {M}_{j-1}^{e} \to \mathcal {M}_{j}^1,\; V_{j}^1:\mathcal {M}_{j}^1 \to \mathcal {M}_{j-1}^{e}$
(which are induced by the Frobenius and Verschiebung, and the definition of
$V_{j}^1$
is a little subtle). Now for each
$1\leq l\leq e$
,
$\mathcal {M}^l = \bigoplus _{j=1}^f \mathcal {M}_{j}^l$
is a locally free
${\mathcal {O}}_S[\varepsilon _1]$
-module with
$\kappa _1$
action, and locally
${\mathcal {M}}^l \simeq \Lambda ^l \otimes _{{\mathcal {O}}_F} {\mathcal {O}}_S.$
For each l, set
$F^l=\bigoplus _jF_{j}^l$
and
$V^l=\bigoplus _jV_{j}^l$
. We have the following linear morphisms:
and semilinear morphisms (
$F^{1}$
is
$\sigma $
-linear and
$V^{1}$
is
$\sigma ^{-1}$
-linear)
Then (see Lemmas 3.7 and 3.6 respectively)
-
(1) For
$2\leq l\leq e$
, we have
$\operatorname {\mathrm {Im}}\,F^l = \operatorname {\mathrm {Ker}}\,V^l, \, \operatorname {\mathrm {Ker}}\,F^l = \operatorname {\mathrm {Im}}\,V^l.$
-
(2) There is a canonical isomorphism
$g: {\mathcal {M}}^1 \to {\mathcal {M}}^1$
sending
$\operatorname {\mathrm {Ker}}\,V^1$
to
$\operatorname {\mathrm {Im}}\,F^1$
.
Therefore we get an F-zip
$$\begin{align*}({\mathcal{M}} = \bigoplus_l {\mathcal{M}}^l, C = \bigoplus_l \operatorname{\mathrm{Ker}}\,F^l, D = \bigoplus_l \operatorname{\mathrm{Ker}}\,V^l, \varphi_{\bullet})\end{align*}$$
over
${\mathscr {A}}_0^{\mathrm {spl}}$
. Moreover, there are natural compatible symplectic forms and
${\mathcal {O}}_L$
-action on
$\mathcal {M}$
. Comparing with the standard F-zip structure on
$\Lambda ^{\mathrm {spl}}_0$
, we get the
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of type
$\mu $
over
${\mathscr {A}}_0^{\mathrm {spl}}$
. Roughly, the process of transforming
$\mathcal {H}$
to
${\mathcal {M}}$
is a way of “semisimplification”. During this transformation the different types of
$\mathcal {G}^{\operatorname {\mathrm {rdt}}}_0$
-zips become uniform as
$\mathcal {G}^{\mathrm {spl}}_0$
-zips, which reflects some key features of the resolution of singularities
${\mathscr {A}}_0^{\mathrm {spl}}\rightarrow {\mathscr {A}}_0$
. Note that even in the Hilbert case, the above construction reveals more complete geometric information than that in [Reference Reduzzi and Xiao56]. For more details, see Proposition 3.8 and subsection 3.2.
Let
$k=\overline {\kappa }$
be an algebraic closure of
$\kappa $
. By Theorem 1.1, we get an induced stratification
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}}_k=\coprod_{w\in {}^JW}{\mathscr{A}}^{\mathrm{spl},w}_k\end{align*}$$
which we call the Ekedahl-Oort (EO) stratification. Here the index set
${}^JW$
is the subset of the (absolute) Weyl group of
$\mathcal {G}^{\mathrm {spl}}_0$
defined by the cocharacter
$\mu $
in the usual way, which is equipped with the partial order
$\preceq $
as that in [Reference Pink, Wedhorn and Ziegler53, Reference Pink, Wedhorn and Ziegler54]. By Theorem 1.1, each stratum
${\mathscr {A}}^{\mathrm {spl},w}_k$
is non-empty, smooth, and we have the usual closure relation for the EO strata given by
$\preceq $
. In fact, the nonemptiness is more subtle, requiring additional efforts. We prove the nonemptiness by comparing the minimal EO stratum of
${\mathscr {A}}^{\mathrm {spl}}_k$
with the minimal EKOR stratum of
${\mathscr {A}}_k$
(see below) in Proposition 3.11, and show the minimal EKOR stratum is nonempty in the Appendix (Proposition A.15) by adapting the method of He-Zhou [Reference He and Zhou26].
We can compare the EO strata with some other naturally raised strata. Recall the natural morphism
$$\begin{align*}\pi:{\mathscr{A}}^{\mathrm{spl}}_k\rightarrow {\mathscr{A}}_k,\end{align*}$$
which is a resolution of singularities: as in the Hilbert case ([Reference Deligne and Pappas13]) the scheme
${\mathscr {A}}_k$
is usually singular in the ramified case. On
${\mathscr {A}}_k$
, we have the following stratifications:
-
• Newton stratification, which can be constructed by studying the associated F-isocrystals with additional structure.
-
• Kottwitz-Rapoport (KR) stratification
${\mathscr {A}}_k=\coprod _{w\in \textrm {Adm}(\mu )_{K_p}}{\mathscr {A}}^{w}_k$
, which is induced from the local model diagram for
${\mathscr {A}}_k$
and the geometry of
$\mathbb {M}^{\mathrm {loc}}_k$
, cf. [Reference Pappas and Rapoport49, Reference Levin40, Reference Haines and Richarz21]. -
• Ekedahl-Kottwitz-Oort-Rapoport (EKOR) stratification
${\mathscr {A}}_k=\coprod _{x\in {}^{K_p}\textrm {Adm}(\mu )}{\mathscr {A}}^{x}_k$
, which can be constructed as in [Reference Shen, Yu and Zhang59], see the Appendix of the current paper; in particular, see Example A.11 for more information on EKOR strata in the Hilbert case.
While on
${\mathscr {A}}^{\mathrm {spl}}_k$
we have the following stratifications:
-
• Newton stratification, which can be constructed by forgetting the splitting structures and considering the associated F-isocrystals with additional structure,
-
• Hodge stratification, which is constructed in [Reference Bijakowski and Hernandez6],
-
• Ekedahl-Oort stratification, which is constructed in this paper.
The Newton stratification on
${\mathscr {A}}^{\mathrm {spl}}_k$
naturally factors through
${\mathscr {A}}_k$
. In subsection 3.6 we will show that the Hodge stratification also factors through
${\mathscr {A}}_k$
. Moreover, the resulting stratification on
${\mathscr {A}}_k$
is coarser than the Kottwitz-Rapoport stratification. On the other hand, the Ekedahl-Oort stratification on
${\mathscr {A}}^{\mathrm {spl}}_k$
does not factor through
${\mathscr {A}}_k$
in general. Nevertheless, one can try to compare the EO strata of
${\mathscr {A}}^{\mathrm {spl}}_k$
with pullbacks of KR and EKOR strata of
${\mathscr {A}}_k$
under
$\pi $
. On each KR stratum
${\mathscr {A}}_k^w$
, we have a
$\mathcal {G}_0^{\textrm {rdt}}$
-zip of type
$J_w$
, see [Reference Shen, Yu and Zhang59] and our Appendix. Pulling back to
${\mathscr {A}}^{\mathrm {spl}}_k$
, we get a family of
$\mathcal {G}_0^{\textrm {rdt}}$
-zips of different types. It is curious to study the relationship with our
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of fixed type
$\mu $
. In doing so, we prove the following results.
Theorem 1.2 (Propositions 3.15 and 3.16).
-
(1) Let
${\mathscr {A}}_k^{w_0}$
be the maximal KR stratum of
${\mathscr {A}}_k$
. Then
$\pi $
induces an isomorphism furthermore
$$\begin{align*}\pi^{-1}({\mathscr{A}}_k^{w_0})\stackrel{\sim}{\rightarrow}{\mathscr{A}}_k^{w_0};\end{align*}$$
$\pi ^{-1}({\mathscr {A}}_k^{w_0})$
is also the maximal Hodge stratum (called the generalized Rapoport locus in [Reference Bijakowski and Hernandez6]).
-
(2)
$\pi ^{-1}({\mathscr {A}}_k^{w_0})$
is a disjoint union of some EO strata of
${\mathscr {A}}^{\mathrm {spl}}_k$
, and moreover these EO strata are exactly pullbacks of the EKOR strata contained in
${\mathscr {A}}_k^{w_0}$
. Thus the isomorphism
$\pi ^{-1}({\mathscr {A}}_k^{w_0})\stackrel {\sim }{\rightarrow }{\mathscr {A}}_k^{w_0}$
refines into isomorphisms between the corresponding EO and EKOR strata.
In particular, using a result of He-Nie [Reference He and Nie24], we can deduce that the maximal EO stratum coincides with the
$\mu $
-ordinary locus, cf. Corollary 3.17. Thus by Theorem 1.1 we reprove the open density of the
$\mu $
-ordinary locus of
${\mathscr {A}}^{\mathrm {spl}}_k$
, cf. [Reference Bijakowski and Hernandez6].
Once we have the morphism
$$\begin{align*}\zeta: {\mathscr{A}}^{\mathrm{spl}}_0\rightarrow \mathcal{G}^{\mathrm{spl}}_0\textrm{-Zip}^\mu_{\kappa},\end{align*}$$
we get Hasse invariants on
$ {\mathscr {A}}^{\mathrm {spl}}_0$
by pulling back the group-theoretic Hasse invariants on the stack
$\mathcal {G}^{\mathrm {spl}}_0\textrm {-Zip}^\mu _{\kappa }$
constructed by Goldring-Koskivirta in [Reference Goldring and Koskivirta20]. Note that in [Reference Bijakowski and Hernandez5] Bijakowski and Hernandez have constructed Hasse invariants for the
$\mu $
-ordinary locus (which is also our maximal EO stratum) by an explicit method. It would be interesting to compare their construction with our construction here. On the other hand, in the Hilbert case, in subsection 4.4 we do compare the EO strata and Hasse invariants here with those constructed in [Reference Reduzzi and Xiao56].
To proceed as in [Reference Reduzzi and Xiao56] and [Reference Goldring and Koskivirta20] to get applications to Galois representations, we need arithmetic compactifications of splitting models and we have to extend the above construction to the compactifications. Fortunately, the arithmetic (toroidal and minimal) compactifications for splitting models with good properties have already been established by Lan in [Reference Lan37], based on his previous constructions in [Reference Lan33, Reference Lan35, Reference Lan36]. At this point, we have to slightly modify the integral model
${\mathscr {A}}^{\mathrm {spl}}={\mathscr {A}}^{\mathrm {spl}}_{K^p}$
by considering the open and closed subspace
$$\begin{align*}\mathsf{M}_K^{\mathrm{spl}}\subset {\mathscr{A}}^{\mathrm{spl}}_{K^p}\end{align*}$$
studied in [Reference Lan37]. Here
$K=K^pK_p$
and
$K_p=\mathcal {G}(\mathbb {Z}_p)$
. All previous constructions and results also hold for
$\mathsf {M}_K^{\mathrm {spl}}$
by simple modifications. For projective and smooth compatible collections of cone decompositions
$\Sigma $
, by [Reference Lan37] we have a toroidal compactification
$\mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}$
, together with a proper surjective morphism to the minimal compactification
$\oint : \mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}\rightarrow \mathsf {M}_{K}^{\mathrm {spl},\mathrm {min}}$
. As we are working with smooth
$\mathsf {M}_K^{\mathrm {spl}}$
, the compactification
$\mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}$
is also smooth by [Reference Lan37] Proposition 3.4.14. We write their special fibers as
$\mathsf {M}^{\mathrm {spl}}_{K,0}$
and
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}$
.
Theorem 1.3 (Theorem 5.4).
-
(1) The
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip of type
$\mu $
on
$\mathsf {M}^{\mathrm {spl}}_{K,0}$
extends to a
$G({\mathbb {A}}_f^p)$
-equivariant
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip of type
$\mu $
on
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}$
. -
(2) The induced map
$\zeta ^{\mathrm {tor}}: \mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}\rightarrow {\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _\kappa $
is smooth.
The extension of
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip is easy to construct, as the canonical extension of the universal de Rham bundle together with its Hodge filtration has already been given by Lan in [Reference Lan37], so we just repeat the above construction. To prove the smoothness of
$\zeta ^{\mathrm {tor}}$
, we adapt some ideas of Andreatta [Reference Andreatta2] in the unramified Hodge-type case. We also prove that EO strata here are well-positioned in the sense of Lan-Stroh [Reference Lan and Stroh38]. By the well-positionedness in fact we get another proof of the smoothness of
$\zeta ^{\mathrm {tor}}$
(this is the approach taken in [Reference Lan and Stroh38] for the unramified PEL case).
Before talking about arithmetic applications, we note another advantage of the smooth splitting models
$\mathsf {M}_K^{\mathrm {spl}}$
. As the modified local model diagram for
$\mathsf {M}_K^{\mathrm {spl}}$
is similar to that in the unramified case, we get naturally automorphic vector bundles on
$\mathsf {M}_K^{\mathrm {spl}}$
as in the classical procedure. In contrast, automorphic vector bundles do not extend to the singular integral model
$\mathsf {M}_K$
, the corresponding open and closed subspace of
${\mathscr {A}}={\mathscr {A}}_{K^p}$
. We also get canonical and subcanonical extensions of automorphic vector bundles to
$\mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}$
, as the local model diagram extends. Moreover, pullbacks of canonical extensions of automorphic vector bundles satisfy similar properties as in the unramified case (cf. [Reference Lan34] Proposition 5.6). In particular, we have the relative vanishing of higher direct images for the projection
$\oint : \mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}\rightarrow \mathsf {M}_{K}^{\mathrm {spl},\mathrm {min}}$
, cf. Proposition 5.3 and [Reference Lan37] Theorem 4.4.9.
Theorems 1.1 and 1.3 allow us to deduce some further consequences on the mod p geometry and arithmetic related to PEL-type Shimura varieties with ramifications arising from Weil restrictions. As an illustration, we discuss congruences of mod p automorphic forms and Galois representations associated to torsion classes in coherent cohomology. For some other possible applications, see [Reference Diamond and Kassaei14] and [Reference Wedhorn and Ziegler66]. From Theorem 1.3, we get extensions of Hasse invariants to toroidal compactifications. Then we can apply Goldring-Koskivirta’s machinery of Hasse-regular sequences introduced in [Reference Goldring and Koskivirta20], which formalizes some key properties of the subschemes defined by Hasse invariants. Indeed, the key technical conditions 6.4.2 and 7.1.2 of [Reference Goldring and Koskivirta20] have been verified in our setting as above. Let S be the finite set of primes
$\ell $
where
$K_\ell $
is not hyperspecial. Let
$P_\mu \subset G_F$
be the parabolic subgroup associated to the cocharacter
$\mu : \mathbb {G}_{m,F}\rightarrow G_F$
in the usual way (see the paragraph above Corollary 2.4),
$\mathbf {L}\subset P_\mu $
the Levi subgroup and
$V_\eta \in \mathrm {Rep}_F\mathbf {L}$
an irreducible representation of highest weight
$\eta $
. Using our modified local model diagram, we get the associated integral automorphic vector bundle
$\mathcal {V}_\eta $
on
$\mathsf {M}_K^{\mathrm {spl}}$
and the subcanonical extension
$\mathcal {V}_\eta ^{\mathrm {sub}}$
of
$\mathcal {V}_\eta $
to
$\mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}$
. For each integers
$i\geq 0, n\geq 1$
, the Hecke algebra
$\mathcal {H}^S$
acts on the cohomology groups
$$\begin{align*}H^i(\mathsf{M}_{K, \Sigma,{\mathcal{O}}_F/\varpi^n}^{\mathrm{spl},\mathrm{tor}}, \mathcal{V}_\eta^{\mathrm{sub}}),\end{align*}$$
where
$\varpi $
is a uniformizer of
${\mathcal {O}}_F$
. Let
$\mathcal {H}^{i,n}_\eta $
be its image in the endomorphism algebra. Fix a representation
$r: {}^LG\rightarrow \mathrm {GL}_m$
of the Langlands dual group over
$\mathbb {C}$
(and fix an isomorphism
$\mathbb {C}\simeq \overline {\mathbb {Q}}_p$
). With all the geometric ingredients at hand, one can prove the following theorem by the same arguments as in [Reference Goldring and Koskivirta20].
Theorem 1.4 (Theorem 6.3).
Suppose that for any regular C-algebraic cuspidal automorphic representation
$\pi '$
of G with
$\pi _{\infty }'$
discrete series, the pair
$(\pi ',r)$
satisfies the condition
$LC_p$
of subsection 6.3, which roughly says the existence of
$\mathrm {GL}_m$
-valued p-adic Galois representation attached to
$\pi '$
satisfying the local-global compatibility outside S.
-
(1) For any
$i\geq 0, n\geq 1, \eta \in X^\ast (T)_{\mathbf {L}}^+$
, there exists a continuous Galois pseudo-representation such that
$$\begin{align*}\rho: \mathrm{Gal}(\overline{\mathbb{Q}}/\mathbb{Q})\longrightarrow \mathcal{H}^{i,n}_\eta, \end{align*}$$
$\rho (\operatorname {\mathrm {Frob}}_v^j)=T_v^{(j)}$
for all
$v\notin S$
, where
$\operatorname {\mathrm {Frob}}_v$
is the geometric Frobenius at v and
$T_v^{(j)}\in \mathcal {H}^{i,n}_\eta $
is the element defined in subsection 6.3.
-
(2) Let
$\pi $
be a C-algebraic cuspidal automorphic representation of G such that
$\pi _\infty $
is a (C-algebraic) nondegenerate limit of discrete series and
$\pi ^{K_p}_p\neq 0$
. Then
$(\pi ,r)$
also satisfies
$LC_p$
.
As [Reference Goldring and Koskivirta20], this theorem is a consequence of a result that the Hecke action on
$H^i$
factorizes through
$H^0$
with increased weight, which is in turn deduced by the machinery of Hasse invariants on toroidal compactifications, see Theorem 6.1.
For the unramified PEL-type case, Theorem 1.4 is due to [Reference Goldring and Koskivirta20] (the key technical conditions 6.4.2 and 7.1.2 there hold for the unramified PEL type case), which recovers the main result of [Reference Emerton, Reduzzi and Xiao16] (for the unramified Hilbert case), and completes the work of Boxer [Reference Boxer7] by a different approach. We refer to [Reference Goldring and Koskivirta20] subsection 10.1 for further discussions on the appearance of nondegenerate limit of discrete series in higher coherent cohomology of Shimura varieties. Recall that since
$K_p\subset G(\mathbb {Q}_p)$
is a very special parahoric subgroup, irreducible smooth representations
$\pi _p$
of
$G(\mathbb {Q}_p)$
such that
$\pi ^{K_p}_p\neq 0$
can be classified by their spherical parameters, see [Reference Zhu71] section 6. The significance of Theorem 1.4 lies in the flexibility it provides for the construction of automorphic Galois representations, in the sense that we allow the p-component of the automorphic representation
$\pi $
to be ramified as
$\pi ^{K_p}_p\neq 0$
. It reproves [Reference Reduzzi and Xiao56] Theorem 1.1 in the Hilbert case by a different method. We also mention that a similar result has been given in [Reference Pilloni and Stroh52] in the ramified setting, but there the integral structure is given by the strange integral models introduced by Scholze using perfectoid geometry. As all these works demonstrate, Theorem 1.4 should be useful when studying modularity lifting problems, cf. [Reference Calegari and Geraghty10].
In this paper we restrict to the PEL case, since so far splitting models for Shimura varieties have only been constructed in this setting ([Reference Pappas and Rapoport49]). It would be interesting and useful to construct splitting models in more general Hodge and abelian type cases. This would certainly require quite different ideas and independent treatments. Once more general splitting models are available, we do expect that our constructions in this paper would naturally extend.
This paper is organized as follows. In section 2, we fix the PEL datum and discuss the corresponding Pappas-Rapoport splitting models. In particular, under a basic assumption on the datum we prove the smoothness of splitting models by a modified local model diagram. In section 3, we construct the universal
$\mathcal {G}^{\mathrm {spl}}_0$
-zip of type
$\mu $
over the smooth special fiber
${\mathscr {A}}^{\mathrm {spl}}_0$
and study the induced Ekedahl-Oort stratification. As an application, we prove the open density of the
$\mu $
-ordinary locus. Along the way we also show that the Hodge stratification constructed in [Reference Bijakowski and Hernandez6] descends to
${\mathscr {A}}_{0}$
. In section 4, we discuss Hasse invariants on
${\mathscr {A}}^{\mathrm {spl}}_0$
, by pulling back those on the zip stack constructed by Goldring-Koskivirta. We also discuss some concrete examples, in particular we compare the Hasse invariants and EO strata here with those constructed by Reduzzi-Xiao in [Reference Reduzzi and Xiao56] in the Hilbert case. In section 5, we first review Lan’s constructions of arithmetic compactifications for splitting models, then we extend the universal
$\mathcal {G}^{\mathrm {spl}}_0$
-zip to the smooth toroidal compactifications
$\mathsf {M}_{K, \Sigma ,0}^{\mathrm {spl},\mathrm {tor}}$
and prove the smoothness of the induced morphism
$\zeta ^{\mathrm {tor}}$
. In section 6, we apply the method of Goldring-Koskivirta [Reference Goldring and Koskivirta20] to deduce similar consequences on Hecke algebras and Galois representations associated to torsion classes in coherent cohomology of smooth splitting models. Finally, in the Appendix we discuss related local model diagrams for general parahoric levels, and briefly review the construction of EKOR stratification on
${\mathscr {A}}_{0}$
.
2 Splitting models of PEL-type Shimura varieties with good reduction
In this section, we review the definition of Pappas-Rapoport splitting models for PEL-type Shimura varieties, following [Reference Pappas and Rapoport49] and [Reference Lan37], for a maximal level at p. In the Appendix A we will work with more general parahoric levels, and discuss the related local model diagrams and EKOR stratifications, which are needed in the main text for the maximal level case. Our setting here is the same as that in [Reference Bijakowski and Hernandez6]. In fact, we will reprove the main results of loc. cit. by a different approach.
2.1 Integral PEL datum
2.1.1 PEL datum
Fix a prime
$p>2$
. Let
$(B, *, V, \left \langle \cdot , \cdot \right \rangle , {\mathcal {O}}_B, \Lambda , h)$
be an integral PEL datum at p. This means (see [Reference Kottwitz30, Reference Rapoport55, Reference Lan33])
-
• B is a finite dimensional semisimple algebra over
$\mathbb {Q}$
with a positive involution
$*$
. We further assume that
$B_{\mathbb {Q}_p}$
is isomorphic to a product of matrix algebras over finite extensions of
$\mathbb {Q}_p$
(note that we allow the extensions to be ramified over
$\mathbb {Q}_p$
). -
• V is a finitely generated faithful B-module.
-
•
$\left \langle \cdot , \cdot \right \rangle : V \times V \to \mathbb {Q}$
is a nondegenerate symplectic form on V such that
$\left \langle bv, w \right \rangle =\left \langle v, b^*w \right \rangle $
for all
$v,w\in V$
and
$b\in B$
. -
•
${\mathcal {O}}_B$
is a
$*$
-invariant
$\mathbb {Z}_{(p)}$
-order of B such that
${\mathcal {O}}_B \otimes \mathbb {Z}_p$
is a maximal
$\mathbb {Z}_p$
-order of
$B_{\mathbb {Q}_p}$
. -
•
$\Lambda $
is a
${\mathcal {O}}_B\otimes \mathbb {Z}_p$
-lattice in
$V_{\mathbb {Q}_p}$
, such that
$\left \langle \cdot , \cdot \right \rangle $
induces a (not necessarily perfect) pairing
$\Lambda \times \Lambda \to \mathbb {Z}_p$
. -
• G is the algebraic group over
$\mathbb {Q}$
of (similitude) automorphisms of
$(V, \left \langle \cdot , \cdot \right \rangle )$
, i.e., for any
$\mathbb {Q}$
-algebra R, we have
$$\begin{align*}G(R) = \{g \in \operatorname{\mathrm{GL}}_B(V_R) \mid \left\langle g z, g z' \right\rangle = c(g) \left\langle z, z' \right\rangle \text{ for some } c(g) \in R^\times, \, \forall\, z, z' \in V_R\}.\end{align*}$$
We further require the group G to be connected.
-
•
$h:\mathbb {S}=\operatorname {\mathrm {Res}}_{\mathbb {C}|\mathbb {R}}(\mathbb {G}_m) \to G_{\mathbb {R}}$
is a group homomorphism that defines a Hodge structure of type
$ \{(-1,0),(0,-1)\}$
on
$V_{\mathbb {R}}$
and the form
$\left \langle \cdot , h(\sqrt {-1})\cdot \right \rangle $
is symmetric and positive definite. (Note that
$(\Lambda ,\left \langle \cdot , \cdot \right \rangle , h)$
is a PEL-type
${\mathcal {O}}_B$
-lattice in the sense of [Reference Lan33] Definition 1.2.1.3.) -
•
$\mu :\mathbb {G}_{m,\mathbb {C}} \to G_{\mathbb {C}}$
is the Hodge cocharacter associated to h.
We make some explicit description of this datum, which will be fixed in the rest of this paper. By assumption, there is a decomposition (as a product of
$*$
-invariant simple factors)
$$\begin{align*}B_{\mathbb{Q}_p} \simeq \prod_{i=1}^r B_i = \prod_{i=1}^r \operatorname{\mathrm{M}}_{m_i}(R_i), \end{align*}$$
where for each
$1\leq i\leq r$
,
$R_i$
is a product of finite extensions (maybe ramified) of
$\mathbb {Q}_p$
. Let
$I := \{1,\dots , r\}$
be the index set. For each
$i \in I$
, let
$F_i$
be the set of
$*$
-invariant elements in
$R_i$
, which is a field over
${\mathbb {Q}}_p$
. Since we require the group G to be connected, we can decompose the index set I into four types: (C), (AL), (AU), and (AR) (see also [Reference Bijakowski and Hernandez6] subsection 2.2, but note that our I is the quotient of their
$\{1,\dots , r\}$
by the induced action of
$\ast $
). For each
$i\in I$
, its type is defined by
-
(C): if
$*$
induces the identity on
$R_i$
, so we have
$R_i = {F_i}$
. -
(AL): if
$R_i \simeq {F_i} \times {F_{i}}$
and
$*$
exchanges the two factors. -
(AU): if
$*$
is an automorphism of order 2 on
$R_i$
, and
$R_i|F_i$
an unramified quadratic extension. -
(AR): if
$*$
is an automorphism of order 2 on
$R_i$
, and
$R_i|F_i$
a ramified quadratic extension.
As in this paper, we are mainly interested in good reduction of splitting models, we will make the following assumption:
$$\begin{align*}\text{For each index } i \in I, \text{ its type is }{not} \text{ (AR)}.\end{align*}$$
Thus our setting is the same as that in [Reference Bijakowski and Hernandez6]. In the unramified case, see also [Reference Viehmann and Wedhorn65] section 2.
For each
$i\in I$
, let
$$\begin{align*}n_i = e_i f_i\end{align*}$$
be the degree of
$F_i$
over
$\mathbb {Q}_p$
, where
$e_i$
is the ramification index and
$f_i$
the residue degree of
$F_i |\mathbb {Q}_p$
. Denote by
$F_i^{\operatorname {\mathrm {ur}}}$
the maximal unramified extension of
$\mathbb {Q}_p$
inside
$F_i$
. Then
$e_i=[F_i: F_i^{\operatorname {\mathrm {ur}}}]$
and
$f_i=[F_i^{\operatorname {\mathrm {ur}}}: \mathbb {Q}_p]$
. The decomposition of
$B_{{\mathbb {Q}}_p}$
induces a decomposition
$$\begin{align*}V_{{\mathbb{Q}}_p} = \bigoplus_{i=1}^r V_i^{m_i}.\end{align*}$$
For each
$i \in I$
, the existence of the
$*$
-symplectic form implies that
$V_i$
is a vector space over
$F_i$
of even dimension, so we write
$$\begin{align*}d_i = \frac{1}{2} \dim_{F_i} V_i,\quad\textrm{thus}\quad \dim_{\mathbb{Q}_p}V_i=2d_in_i.\end{align*}$$
We have an isomorphism
$$\begin{align*}{\mathcal{O}}_B\otimes\mathbb{Z}_p\simeq \prod_{i=1}^r\operatorname{\mathrm{M}}_{m_i}({\mathcal{O}}_{R_i})\end{align*}$$
with
${\mathcal {O}}_{R_i}$
the maximal order of
$R_i$
, and the induced decomposition
$$\begin{align*}\Lambda = \bigoplus_{ i=1}^r \Lambda_i^{m_i},\end{align*}$$
where each
$\Lambda _i$
is an
${\mathcal {O}}_{R_i}$
-lattice in
$V_i$
, and there is an induced pairing
$\langle \cdot ,\cdot \rangle _i: \Lambda _i\times \Lambda _i\rightarrow {\mathcal {O}}_{R_i}$
if i is of type (C) or (AL), and
$\langle \cdot ,\cdot \rangle _i: \Lambda _i\times \Lambda _i\rightarrow {\mathcal {O}}_{F_i}$
if i is of type (AU).
2.1.2 Rational group structure
The restriction of the pairing
$\langle \cdot ,\cdot \rangle $
on
$V_i$
defines an algebraic group
$G_i=\operatorname {\mathrm {Res}}_{F_i|\mathbb {Q}_p}H_i$
over
${\mathbb {Q}}_p$
: for any
$F_i$
-algebra R, we have
$$\begin{align*}H_i(R) = \{g_i \in \operatorname{\mathrm{GL}}_{B_i}(V_{i,R}) \mid \left\langle g_i x, g_i y \right\rangle = c_i(g_i) \left\langle x, y \right\rangle \text{ for some } c_i(g_i) \in R^\times,\,\forall\, x,y \in V_{i,R}\}.\end{align*}$$
Then
$$\begin{align*}G_{{\mathbb{Q}}_p} \subset \prod_{i \in I}G_i\end{align*}$$
is the subgroup such that the local similitude factors
$c_i$
are the same and defined over
$\mathbb {Q}_p$
. From now on, we fix an isomorphism of fields
$\mathbb {C} \simeq \overline {\mathbb {Q}}_p$
. Then we view
$\mu $
as a cocharacter of G over
$\overline {\mathbb {Q}}_p$
. Let F be a fixed sufficiently large finite Galois extension of
$\mathbb {Q}_p$
containing all embeddings of
$F_i$
to
$\overline {\mathbb {Q}}_p$
such that
$G_F$
is split. Then the cocharacter
$\mu $
is defined over F and we can write
$$\begin{align*}\mu: {\mathbb{G}}_{m,F} \to G_F \subset \prod_{i\in I} G_{i,F}.\end{align*}$$
For each
$i\in I$
, the projection of
$G_F$
to
$G_{i,F}$
induces a cocharacter
$$\begin{align*}\mu_i: {\mathbb{G}}_{m,F} \to G_{i,F}.\end{align*}$$
For each
$i \in I$
, we order the embeddings
$ F_i^{\mathrm {ur}} \hookrightarrow F$
as
$\sigma _{i,1},\dots \,\sigma _{i,f_i}$
. For each
$1\leq j\leq f_i$
, there are
$e_i$
extensions of
$\sigma _{i,j}$
to embeddings
$F_i\hookrightarrow F$
, ordered and denoted by
$\sigma _{i,j}^l: F_i \to F$
, for
$1\leq l \leq e_i$
. We have the decompositions
$$\begin{align*}V_{i,F} = \bigoplus_{j=1}^{f_i} V_{i,j},\quad V_{i,j} = \bigoplus_{l=1}^{e_i} V_{i,j}^l.\end{align*}$$
For each
$1\leq j\leq f_i$
, the space
$V_{i,j}$
is the subspace of
$V_{i,F}$
such that
$F_i^{\mathrm {ur}}$
acts through
$\sigma _{i,j}$
, and for each
$1\leq l\leq e_i$
the space
$V_{i,j}^l$
is the subspace of
$V_{i,j}$
such that
$F_{i}$
acts through
$\sigma _{i,j}^l$
. Note that we also have
$$\begin{align*}2 d_i = \operatorname{\mathrm{rank}}_{F} V_{i,j}^l,\end{align*}$$
and the pairing
$\langle \cdot ,\cdot \rangle $
on
$V_i$
induces pairings
$\langle \cdot ,\cdot \rangle : V_{i,j}^l\times V_{i,j}^l\rightarrow F$
(which in fact are defined over
$F_i$
). For each
$i \in I$
, as
$G_i = \operatorname {\mathrm {Res}}_{F_i|{\mathbb {Q}}_p} H_i$
, we have
$$\begin{align*}G_{i,F} = \prod_{\sigma_{i,j}^l: F_i \to F} G_{i,j}^l,\end{align*}$$
where in the index
$\sigma _{i,j}^l$
runs through all
$1\leq j\leq f_i$
and
$1\leq l\leq e_i$
, and each
$G_{i,j}^l$
is (isomorphic to) a copy of
$H_{i,F}$
. So the cocharacter
$$\begin{align*}\mu_i: {\mathbb{G}}_{m,F} \to G_{i,F} = \prod_{j,l} G_{i,j}^l,\end{align*}$$
induces a cocharacter
$$\begin{align*}\mu_{i,j}^l: {\mathbb{G}}_{m,F} \to G_{i,j}^l\end{align*}$$
for each
$1\leq j\leq f_i$
and
$1\leq l \leq e_i$
.
Since the only weights of
$\mu : \mathbb {G}_{m,F} \to G_{F}$
are
$0$
and
$1$
, we get an induced decomposition
$$\begin{align*}V_{F} = W \oplus W',\end{align*}$$
where
$z \in F^\times $
acts on W (resp.
$W'$
) by 1 (resp. z). This implies that the pairing
$\langle \cdot ,\cdot \rangle $
induces an isomorphism
$$\begin{align*}W \simeq (W')^\vee := \operatorname{\mathrm{Hom}}_{F}(W', F).\end{align*}$$
We can also decompose the F-vector space W as
$$\begin{align*}W = \bigoplus_{i=1}^r W_i^{m_i}, \quad W_i = \bigoplus_{j=1}^{f_i} W_{i,j}\quad \text{ and } \quad W_{i,j} = \bigoplus_{l=1}^{e_i} W_{i,j}^l.\end{align*}$$
We have similar decompositions for
$W'$
. For each
$i,j,l$
, we have
$V_{i,j}^l=W_{i,j}^l\oplus (W')_{i,j}^l$
. Let
$d_{i,j}^l = \dim _F W_{i,j}^l$
. If we write
$d_{i,j}^l = d_{\sigma _{i,j}^l}$
to make explicit the embedding
$\sigma _{i,j}^l$
, then there is an induced
$*$
-action on
$\{\sigma _{i,j}^l\}_{i,j,l}$
and we set
$(d_{i,j}^l)^* := d_{(\sigma _{i,j}^l)^*}$
. The natural isomorphism
$W \simeq (W')^\vee $
gives the identity
$$\begin{align*}(d_{i,j}^l)^* = \dim_F (W')_{i,j}^l,\quad \text{ and }\quad d_{i,j}^l + (d_{i,j}^l)^* = 2 d_i.\end{align*}$$
We can make these data more explicit according to the type of i: recall
$G_i=\operatorname {\mathrm {Res}}_{F_i|\mathbb {Q}_p}H_i$
-
(C): in this case
$R_i=F_i$
,
$\dim _{F_i}V_i=2d_i$
,
$H_i\simeq \operatorname {\mathrm {GSp}}_{2d_i}$
. We have for each
$$\begin{align*}d_{i,j}^l=\dim_FW_{i,j}^l=\dim_F (W')_{i,j}^l=d_i\end{align*}$$
$1\leq j\leq f_i$
and
$1\leq l\leq e_i$
.
-
(AL): in this case
$R_i=F_i\times F_i$
, so we have a decomposition with
$$\begin{align*}V_i=U_i\oplus U_i^{\vee}\end{align*}$$
$\dim _{F_i}U_i=d_i$
,
$H_i\simeq \operatorname {\mathrm {GL}}_{d_i}\times \mathbb {G}_m$
. Then there are induced decompositions
$V_{i,j}^l=U_{i,j}^l\oplus (U^\vee )_{i,j}^{l}$
,
$W_{i,j}^l=A_{i,j}^l\oplus (A^\vee )_{i,j}^l$
and
$(W')_{i,j}^l=(A')_{i,j}^l\oplus ((A')^\vee )_{i,j}^{ l}$
. Let
$a_{i,j}^l=\dim _F A_{i,j}^l, b_{i,j}^l=\dim _F(A')_{i,j}^l$
, then by similar notations as above for each
$$\begin{align*}(a_{i,j}^l)^\ast=b_{i,j}^l \quad \textrm{and}\quad a_{i,j}^l+b_{i,j}^l=d_i\end{align*}$$
$1\leq j\leq f_i$
and
$1\leq l\leq e_i$
.
-
(AU): in this case
$R_i|F_i$
is an unramified quadratic extension, and
$V_i$
is a Hermitian space over
$R_i|F_i$
,
$H_i=\textrm {GU}(V_i,\langle \cdot ,\cdot \rangle _i)$
. We have
$W_{i,j}^l=A_{i,j}^l\oplus B_{i,j}^l$
and
$(W')_{i,j}^l=(A')_{i,j}^l\oplus (B')_{i,j}^l$
. Let
$a_{i,j}^l=\dim _F A_{i,j}^l, b_{i,j}^l=\dim _F(A')_{i,j}^l$
, then by similar notations as above for each
$$\begin{align*}(a_{i,j}^l)^\ast=b_{i,j}^l \quad \textrm{and}\quad a_{i,j}^l+b_{i,j}^l=d_i\end{align*}$$
$1\leq j\leq f_i$
and
$1\leq l\leq e_i$
.
In the rest of the paper, the index
$(i,j,l)$
will always be a tuple of integers running through
$i \in I, 1\leq j \leq f_i$
and
$0 \leq l \leq e_i$
.
2.1.3 Integral group structure
Now we discuss the integral group-theoretic data that will be needed later. Consider the parahoric group scheme
$\mathcal {G}$
over
$\mathbb {Z}_p$
defined by the integral PEL datum
$({\mathcal {O}}_B, \ast ,\Lambda , \langle \cdot ,\cdot \rangle )$
. Recall the decomposition
$\Lambda = \bigoplus _{ i=1}^r \Lambda _i^{m_i}$
, where each
$\Lambda _i$
is an
${\mathcal {O}}_{R_i}$
-lattice in
$V_i$
together with an induced form
$\langle \cdot ,\cdot \rangle _i: \Lambda _i\times \Lambda _i\rightarrow {\mathcal {O}}_{R_i}$
(i of type (C) or (AL)) or
$\langle \cdot ,\cdot \rangle _i: \Lambda _i\times \Lambda _i\rightarrow {\mathcal {O}}_{F_i}$
(i of type (AU)). Let
${\mathcal {G}}_i / {\mathbb {Z}}_p$
be the parahoric subgroup of
$G_i$
associated to
$(\Lambda _i, \langle \cdot ,\cdot \rangle _i)$
, then
$$\begin{align*}\mathcal{G}\subset \prod_{i\in I} \mathcal{G}_i\end{align*}$$
is the subgroup of elements with the same local similitude factors defined over
$\mathbb {Z}_p^\times $
. For each i, the
${\mathcal {O}}_{F_i}$
-lattice
$\Lambda _i$
is self dual with respect to the form
$\langle \cdot ,\cdot \rangle _i$
, so that the above group
$H_i$
is unramified over
$F_i$
. By abuse of notation, we still denote by
$H_i$
its reductive integral model over
${\mathcal {O}}_{F_i}$
. Then we have
$$\begin{align*}{\mathcal{G}}_{i} = \operatorname{\mathrm{Res}}_{{\mathcal{O}}_{F_i}|{\mathbb{Z}}_p} H_i.\end{align*}$$
Recall that we have fixed a large enough field extension
$F|\mathbb {Q}_p$
. Let
$\kappa $
(resp.
$\kappa _i$
for each
$i\in I$
) be the residue field of F (resp.
$F_i$
for each
$i\in I$
). For each
$i\in I$
, we denote also by
$H_i$
the associated reductive group over
$\kappa _i$
. Consider the artinian
$\kappa _i$
-algebra defined by the quotient of the polynomial ring
$\kappa _i[\varepsilon _i] := \kappa _i[x]/(x^{e_i})$
. Then we have
$$\begin{align*}{\mathcal{G}}_{i,0}:={\mathcal{G}}_i \otimes_{{\mathbb{Z}}_p} {\mathbb{F}}_p \simeq \operatorname{\mathrm{Res}}_{\kappa_i[\varepsilon_i]|{\mathbb{F}}_p} H_i.\end{align*}$$
By [Reference Oesterlé44, Appendice 3], there is an exact sequence
$$\begin{align*}1 \to U \to {\mathcal{G}}_{i,0} \to \operatorname{\mathrm{Res}}_{\kappa_i |{\mathbb{F}}_p} H_i \to 1,\end{align*}$$
where U is a connected unipotent subgroup of
${\mathcal {G}}_{i,0}$
. Let
${\mathcal {G}}_{i,0}^{\operatorname {\mathrm {rdt}}}$
be the maximal reductive quotient of
${\mathcal {G}}_{i,0}$
. So we have
$$\begin{align*}{\mathcal{G}}_{i,0}^{\operatorname{\mathrm{rdt}}} \simeq \operatorname{\mathrm{Res}}_{\kappa_i|{\mathbb{F}}_p} H_i.\end{align*}$$
This group is the similitude automorphism group associated to
$$\begin{align*}\Lambda_{i,0}^{\operatorname{\mathrm{rdt}}} := \Lambda_{i,0} \otimes_{\kappa_i[\varepsilon_i]}\kappa_i,\quad\textrm{where}\quad \Lambda_{i,0}=\Lambda_i\otimes_{\mathbb{Z}_p}{\mathbb{F}}_p,\end{align*}$$
which admits an induced
$\kappa _i[\varepsilon _i]$
-action and a pairing
$\langle \cdot ,\cdot \rangle _i: \Lambda _{i,0}\times \Lambda _{i,0}\rightarrow \kappa _i$
(for i of type (C) or (AU)) or
$\langle \cdot ,\cdot \rangle _i: \Lambda _{i,0}\times \Lambda _{i,0}\rightarrow \kappa _i\times \kappa _i$
(for i of type (AL)). Let
${\mathcal {G}}_{0}^{\operatorname {\mathrm {rdt}}}$
be the maximal reductive quotient of
${\mathcal {G}}_{0}$
. We have similarly an inclusion
$$\begin{align*}{\mathcal{G}}_{0}^{\operatorname{\mathrm{rdt}}}\subset \prod_{i\in I}{\mathcal{G}}_{i,0}^{\operatorname{\mathrm{rdt}}}.\end{align*}$$
2.1.4 The group
${\mathcal {G}}_0^{\mathrm {spl}}$
For each
$i\in I$
, we define the group
${\mathcal {G}}_{i,0}^{\mathrm {spl}} / {\mathbb {F}}_p$
as the similitude automorphism group associated to
$(\Lambda _{i,0}^{\operatorname {\mathrm {rdt}}})^{e_i}$
with its natural pairing. Then we have an isomorphism
$$\begin{align*}{\mathcal{G}}_{i,0}^{\mathrm{spl}} \simeq\operatorname{\mathrm{Res}}_{\kappa_i|{\mathbb{F}}_p} H_i^{e_i}.\end{align*}$$
Putting together, we define
$$\begin{align*}\mathcal{G}^{\mathrm{spl}}_0\subset\prod_{i\in I}{\mathcal{G}}_{i,0}^{\mathrm{spl}}\end{align*}$$
as the subgroup of element with the same
$\mathbb {F}_p$
-local similitude factors. For each
$i\in I, 1\leq j\leq f_i,1\leq l\leq e_i$
, by our choice of F,
$G_{i,j}^l$
is a split reductive group over F. We denote by the same notations the reductive group scheme over
${\mathcal {O}}_F$
and
$\kappa $
. Then each
$\mu _{i,j}^l$
extends to a cocharacter of
$G_{i,j}^l$
over
${\mathcal {O}}_F$
and thus a cocharacter over
$\kappa $
:
$$\begin{align*}\mu_{i,j}^l: {\mathbb{G}}_{m,\kappa} \to G_{i,j}^l.\end{align*}$$
The cocharacters
$\mu _{i,j}^l$
then define a cocharacter of
$\prod _{i\in I}\mathcal {G}^{\mathrm {spl}}_{i,0}$
over
$\kappa $
. One can check carefully that it factors through
$\mathcal {G}^{\mathrm {spl}}_{0,\kappa }$
:
$$\begin{align*}\mu= \prod_{i,j,l} \mu_{i,j}^l : {\mathbb{G}}_{m,\kappa} \to \mathcal{G}^{\mathrm{spl}}_0\otimes_{\mathbb{F}_p}\kappa \subset \prod_{i,j,l} G_{i,j}^l.\end{align*}$$
Fix an
$i\in I$
. For each
$1\leq j \leq f_i, 1 \leq l \leq e_i$
, we also define an
${\mathcal {O}}_F$
-lattice as
$$\begin{align*}\Lambda_{i,j}^l := \Lambda_i \otimes_{{\mathcal{O}}_{F_i},\sigma_{i,j}^l} {\mathcal{O}}_F.\end{align*}$$
The pairing on
$\Lambda _i$
induces a natural pairing on the
${\mathcal {O}}_F$
-lattice
$\Lambda _{i,j}^l$
, and the similitude automorphism group is isomorphic to
$G_{i,j}^l$
over
${\mathcal {O}}_F$
. In contrast to the rational case, in general
${\mathcal {G}}_{i,{\mathcal {O}}_F}$
does not split as a product of
$G_{i,j}^l$
due to ramification. So we define the split
${\mathcal {O}}_F$
-lattice as
$$\begin{align*}\Lambda^{\mathrm{spl}} := \bigoplus_{i \in I} \Lambda_i^{\mathrm{spl},m_i},\quad \Lambda_i^{\mathrm{spl}} := \bigoplus_{j,l} \Lambda_{i,j}^l,\end{align*}$$
where and in the following the indexes j and l (in the second direct sum) run over
$1\leq j\leq f_i$
and
$1\leq l\leq e_i$
. There are naturally induced pairings on
$\Lambda ^{\mathrm {spl}} $
and
$\Lambda _i^{\mathrm {spl}} $
. Let
$\mathcal {G}^{\mathrm {spl}}$
and
$\mathcal {G}^{\mathrm {spl}}_i$
be the corresponding group schemes over
${\mathcal {O}}_F$
. Then
$\mathcal {G}^{\mathrm {spl}}_i=\prod _{j,l}G_{i,j}^l$
, and we have the inclusion as before
$$\begin{align*}\mathcal{G}^{\mathrm{spl}}\subset \prod_{i\in I}\mathcal{G}^{\mathrm{spl}}_i\end{align*}$$
by requiring having the same
$\mathbb {Z}_p^\times $
-local similitude factors. Over F we have the following isomorphism
$$\begin{align*}\Lambda_i^{\mathrm{spl}} \otimes_{{\mathcal{O}}_F} F \simeq V_i \otimes_{{\mathbb{Q}}_p} F,\end{align*}$$
compatible with additional structures on both sides. Thus
$\mathcal {G}^{\mathrm {spl}}$
is the split reductive model of G over F. Note that there is a natural homomorphism
$$\begin{align*}\mathcal{G}_{i,{\mathcal{O}}_F}\rightarrow \mathcal{G}^{\mathrm{spl}}_i\end{align*}$$
which is not an isomorphism in general as remarked above. Therefore, in general we have
$$\begin{align*}\mathcal{G}_{{\mathcal{O}}_F}\ncong \mathcal{G}^{\mathrm{spl}}.\end{align*}$$
For each
$i\in I, 1\leq j\leq f_i,1\leq l\leq e_i$
, set
$$\begin{align*}\Lambda_{i,j,0}^l=\Lambda_{i,j}^l\otimes_{{\mathcal{O}}_F}\kappa \quad \textrm{and} \quad \Lambda_{i,0}^l = \bigoplus_{j=1}^{f_i} \Lambda_{i,j,0}^l.\end{align*}$$
For each
$1 \leq l \leq e_i$
, we have the natural isomorphism
$$\begin{align*}\Lambda_{i,0}^{\operatorname{\mathrm{rdt}}} \otimes_{\mathbb{F}_p} \kappa \simeq \Lambda_{i,0}^l = \bigoplus_{j=1}^{f_i} \Lambda_{i,j,0}^l.\end{align*}$$
Therefore,
$$\begin{align*}\Lambda_{i,0}^{\mathrm{spl}} := \Lambda_{i}^{\mathrm{spl}} \otimes_{{\mathcal{O}}_F} \kappa=\bigoplus_{j,l}\Lambda_{i,j,0}^l=\Lambda_{i,0}^{\operatorname{\mathrm{rdt}}, e_i}\otimes_{\mathbb{F}_p}\kappa.\end{align*}$$
So
${\mathcal {G}}_{i,0}^{\mathrm {spl}} \otimes \kappa $
is the similitude automorphism group associated to
$\Lambda _{i,0}^{\mathrm {spl}}$
, and
$\mu _i$
is a cocharacter of
${\mathcal {G}}_{i,0}^{\mathrm {spl}}$
defined over
$\kappa $
. By construction, we have an isomorphism of reductive groups over
$\kappa $
:
$$\begin{align*}\mathcal{G}^{\mathrm{spl}}_0\otimes_{\mathbb{F}_p}\kappa\simeq \mathcal{G}^{\mathrm{spl}}\otimes_{{\mathcal{O}}_F}\kappa.\end{align*}$$
In other words,
$\mathcal {G}^{\mathrm {spl}}_0$
is an
$\mathbb {F}_p$
model of the special fiber of
$\mathcal {G}^{\mathrm {spl}}$
. Moreover, one can analyze the decomposition of
$\Lambda _{i,0}^{\mathrm {spl}}$
induced by
$\mu _i$
exactly as in the characteristic zero case (see the end of in 2.1.2).
2.2 Smooth Pappas-Rapoport splitting models
Recall that we have
$\mu : \mathbb {G}_{m,\overline {\mathbb {Q}}_p}\rightarrow G_{\overline {\mathbb {Q}}_p}$
the Hodge cocharacter of G over
$\overline {\mathbb {Q}}_p$
. Let E be the field of definition of the conjugacy class attached to
$\mu $
. Then by the assumption on F, we have
$E\subset F$
.
Let
$K^p$
be a sufficiently small open compact subgroup of
$G(\mathbb {A}_f^p)$
, which will be fixed in the rest of this section. By works of Kottwitz [Reference Kottwitz30] and Rapoport-Zink [Reference Rapoport55], there is a scheme
$\mathscr {A}^{\operatorname {\mathrm {naive}}}=\mathscr {A}^{\operatorname {\mathrm {naive}}}_{K^p}$
over
${\mathcal {O}}_E$
representing the following moduli problem (see [Reference Rapoport55] chapter 6 for more details): for any
${\mathcal {O}}_E$
-scheme S,
$\mathscr {A}^{\operatorname {\mathrm {naive}}}(S)$
classifies the isogeny classes of tuples
$(A,\lambda ,\iota ,\alpha )$
, where
-
•
$A /S$
is an abelian scheme, -
•
$\lambda : A \to A^\vee $
is a
$\mathbb {Z}_{(p)}^\times $
-polarization, -
•
$\iota : {\mathcal {O}}_B \to \operatorname {\mathrm {End}}_S(A)\otimes _{\mathbb {Z}} \mathbb {Z}_{(p)}$
is an
${\mathcal {O}}_B$
-structure of
$(A,\lambda )$
, which is compatible with the Rosatti involution. -
•
$\alpha $
is a
$K^p$
-level structure.
Its generic fiber
$\mathscr {A}^{\operatorname {\mathrm {naive}}}_E$
is called the rational moduli space with respect to the PEL datum.
For any
${\mathcal {O}}_E$
-scheme S and a point
$\underline {A} \in \mathscr {A}^{\operatorname {\mathrm {naive}}}(S)$
, there is an exact sequence of
${\mathcal {O}}_S$
-modules
$$\begin{align*}0 \to \omega_{A/S} \to H_{\operatorname{\mathrm{dR}}}^1(A/S) \to \operatorname{\mathrm{Lie}}_{A^\vee/S} \to 0,\end{align*}$$
where
$\omega _{A/S}$
is the sheaf of invariant differentials. For simplicity, write
$\omega = \omega _{A/S}$
, and
${\mathcal {H}} = H^1_{\operatorname {\mathrm {dR}}}(A/S)$
. The action of
${\mathcal {O}}_B\otimes \mathbb {Z}_p$
on the
${\mathcal {O}}_S$
-modules
${\mathcal {H}}$
and
$\omega $
induces decompositions
$$\begin{align*}{\mathcal{H}}=\bigoplus_{i\in I}{\mathcal{H}}_i^{m_i},\quad {\mathcal{H}}_i=\bigoplus_{j=1}^{f_i}{\mathcal{H}}_{i,j},\quad \omega = \bigoplus_{i\in I} \omega_i^{m_i},\quad \omega_i = \bigoplus_{j=1}^{f_i} \omega_{i,j},\end{align*}$$
and similarly for
$\operatorname {\mathrm {Lie}}_{A^\vee /S}$
. For each
$i, j$
, we have an exact sequence of
${\mathcal {O}}_S$
-modules
$$\begin{align*}0 \to \omega_{i,j} \to \mathcal{H}_{i,j} \to \operatorname{\mathrm{Lie}}_{A^\vee/S, i, j} \to 0.\end{align*}$$
As
$\iota $
is compatible with
$\lambda $
, there is an isomorphism
$$\begin{align*}\mathcal{H}_{i,j} \simeq \mathcal{H}_{i,j}^{\vee}.\end{align*}$$
${\mathcal {H}}_{i,j}$
is a self-dual
${\mathcal {O}}_S$
-module of rank
$2d_i e_i$
. If i is an index of type (AL), there is a natural decomposition
${\mathcal {H}}_{i,j} = {\mathcal {H}}^{\prime }_{i,j} \times {\mathcal {H}}_{i,j}^{'\vee }$
such that
${\mathcal {H}}_{i,j}'$
is an
${\mathcal {O}}_S$
-module and
${\mathcal {H}}_{i,j}^{'\vee }:=\operatorname {\mathrm {Hom}}({\mathcal {H}}^{\prime }_{i,j}, {\mathcal {O}}_S)$
. Moreover, the pairing of
${\mathcal {H}}_{i,j}$
is given by the natural pairing of product of dual objects.
For each
$i\in I$
, let
$\pi _i$
be a uniformizer of
${\mathcal {O}}_{F_i}$
. Moreover, for each triple
$(i,j,l)$
, set
$$\begin{align*}\pi_{i,j}^l = \sigma_{i,j}^l(\pi_i).\end{align*}$$
For each
$i, j, l$
, we define two polynomials as
$$\begin{align*}Q_{i,j}^{\leq l}(T) = \prod_{k=1}^l (T-\pi_{i,j}^k)\quad \text{ and }\quad Q_{i,j}^{>l}(T) = \prod_{k=l+1}^{e_i} (T- \pi_{i,j}^k).\end{align*}$$
Definition 2.1 (See also Definition A.4).
Let S be an
${\mathcal {O}}_F$
-scheme and
$\underline {A} = (A,\iota ,\lambda ,\alpha ) \in \mathscr {A}^{\operatorname {\mathrm {naive}}}(S)$
with the associated
$\mathcal {H}$
and
$\omega $
together with the induced additional structure. A splitting structure with respect to
$\underline {A}$
is given by the datum
$\underline {\mathscr {F}_{\bullet }}=(\mathscr {F}_{i,j}^l)$
: for each
$i\in I, 1\leq j\leq f_i$
, there is a filtration of
$\mathcal {O}_S$
-modules with
${\mathcal {O}}_{F_i}$
-action
$$\begin{align*}0 = \mathscr{F}_{i,j}^0 \subset \mathscr{F}_{i,j}^1 \subset \cdots \subset \mathscr{F}_{i,j}^{e_i} = \omega_{i,j},\end{align*}$$
such that
-
(1) For each
$1\leq l\leq e_i$
,
$\mathscr {F}_{i,j}^l$
and
$\mathcal {H}_{i,j} / \mathscr {F}_{i,j}^l$
are finite locally free
$\mathcal {O}_S$
-modules. -
(2) Write
$[\pi _i]$
for the action of
$\pi _i \in {\mathcal {O}}_{F_i}$
. Then for all
$1\leq l \leq e_i$
, we have i.e.,
$$\begin{align*}([\pi_i] - \pi_{i,j}^l)\cdot \mathscr{F}_{i,j}^l \subset \mathscr{F}_{i,j}^{l-1},\end{align*}$$
$(\pi _i \otimes 1 - 1 \otimes \sigma _{i,j}^l (\pi _i)) \cdot \mathscr {F}_{i,j}^l \subset \mathscr {F}_{i,j}^{l-1}$
.
-
(3) The
$\mathcal {O}_S$
-module
$\mathscr {F}_{i,j}^l / \mathscr {F}_{i,j}^{l-1}$
is locally free of rank
$d_{i,j}^l$
for all
$1 \leq l \leq e_i$
. -
(4) For each
$1 \leq l \leq e_i$
, let
$\mathscr {F}_{i,j}^{e_i+l} = {Q_{i,j}^{>e_i-l}(\pi _i)}^{-1}\mathscr {F}_{i,j}^{e_i-l}$
. Then we require that
$$\begin{align*}\mathscr{F}_{i,j}^{e_i+l} =\mathscr{F}_{i,j}^{e_i-l, \perp}\quad \textrm{and}\quad ([\pi_i] - \pi_{i, j}^{e_i}) \cdots ([\pi_i] - \pi_{i, j}^{e_i+l-1}) \mathscr{F}_{i, j}^{e_i+l} \subset \mathscr{F}_{i, j}^{e_i-l}.\end{align*}$$
Here
$\mathscr {F}_{i,j}^{e_i-l, \perp }$
is the orthogonal complement of
$\mathscr {F}_{i,j}^{e_i-l}$
in
${\mathcal {H}}_{i,j}$
under the pairing on
${\mathcal {H}}_{i,j}$
induced by the polarization
$\lambda $
.
More explicitly, we have the following description of splitting structures according to the type of i (see the notations in 2.1.2; see also [Reference Bijakowski and Hernandez6] subsections 2.3 and 2.4):
-
• (C): We have
$R_i = F_i$
and for each index
$i, j, l$
,
$d_{i, j}^l = d_i$
. One has a filtration where for each
$$\begin{align*}0 = \mathscr{F}_{i, j}^0 \subset \mathscr{F}_{i, j}^1 \subset \cdots \subset \mathscr{F}_{i, j}^{e_i} = \omega_{i, j} \subset {\mathcal{H}}_{i, j},\end{align*}$$
$1\leq l\leq e_i$
,
${\mathscr {F}}_{i, j}^l$
is a locally a direct factor of rank
$d_i l$
, and the filtration satisfies the relations as in conditions (2) and (4) above.
-
• (AL): We have
$R_i = F_i \times F_i$
, and
${\mathcal {H}}_{i} = {\mathcal {H}}_i' \oplus {\mathcal {H}}_i^{'\vee }$
. For each j, the splitting structure is reduced to a filtration where each
$$\begin{align*}0 = \mathscr{F}_{i, j}^0 \subset \mathscr{F}_{i, j}^1 \subset \cdots \subset \mathscr{F}_{i, j}^{e_i} = \omega_{i, j}' \subset {\mathcal{H}}_{i, j}',\end{align*}$$
${\mathscr {F}}_{i, j}^l$
is locally a direct factor of rank
$a_{i, j}^1 + \cdots + a_{i, j}^l$
, and the filtration satisfies condition (2) above.
-
• (AU): We have a quadratic unramified field extension
$R_i|F_i$
. For each j, we have a further decomposition given by the unramified
$$\begin{align*}\omega_{i, j} = \omega_{i, j}' \oplus (\omega_{i, j}')^\vee\end{align*}$$
${\mathcal {O}}_{R_i}$
-action, and the splitting structure is reduced to a filtration where each
$$\begin{align*}0 = \mathscr{F}_{i, j}^0 \subset \mathscr{F}_{i, j}^1 \subset \cdots \subset \mathscr{F}_{i, j}^{e_i} = \omega_{i, j}' \subset {\mathcal{H}}_{i, j},\end{align*}$$
${\mathscr {F}}_{i, j}^l$
is locally a direct factor of rank
$a_{i, j}^1 + \cdots + a_{i, j}^l$
, and the filtration satisfies the above condition (2).
Finally, we can give the definition of the splitting model over
$\mathscr {A}^{\operatorname {\mathrm {naive}}}$
, cf. [Reference Pappas and Rapoport49].
Definition 2.2. The splitting model
$\mathscr {A}^{\mathrm {spl}}$
over
${\mathcal {O}}_F$
is the scheme that represents the following moduli problem: for any scheme S over
${\mathcal {O}}_F$
,
$\mathscr {A}^{\mathrm {spl}}(S)$
is the isomorphism classes of tuples
$(\underline {A},\underline {\mathscr {F}_{\bullet }})$
, where
-
•
$\underline {A} = (A, \lambda , \iota , \alpha )$
is an S-point of
$\mathscr {A}^{\operatorname {\mathrm {naive}}}$
. -
•
$\underline {\mathscr {F}_{\bullet }} = (\mathscr {F}_{i,j}^l) $
is a splitting structure of
$\underline {A}$
. -
• The isomorphism is given by
$\mathbb {Z}_{(p)}^\times $
-isogenies between abelian schemes with
${\mathcal {O}}_B$
-structures and splitting structure.
Let
$A^{\textrm {univ}}$
be the universal abelian scheme over
$\mathscr {A}^{\operatorname {\mathrm {naive}}}$
with the associated
$\mathcal {H}$
and
$\omega $
. By the notation of [Reference Lan37], we have
$$\begin{align*}\mathscr{A}^{\mathrm{spl}}=\mathrm{Spl}^+_{(\mathcal{H},\omega,\iota)/\mathscr{A}^{\operatorname{\mathrm{naive}}}\otimes {\mathcal{O}}_F}. \end{align*}$$
By [Reference Pappas and Rapoport49] section 15 and [Reference Lan37] Lemma 2.3.9, there is a canonical isomorphism of schemes over F
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}} \otimes_{{\mathcal{O}}_F} F \simeq \mathscr{A}^{\operatorname{\mathrm{naive}}} \otimes_{{\mathcal{O}}_E} F.\end{align*}$$
Proposition 2.3. Assume that each
$i\in I$
has type either (C), or (AL), or (AU), then the splitting model
${\mathscr {A}}^{\mathrm {spl}}$
is smooth over
${\mathcal {O}}_F$
.
Proof. Let
$\widetilde {\mathscr {A}^{\mathrm {spl}}}$
be the scheme over
${\mathcal {O}}_F$
such that for any
${\mathcal {O}}_F$
-scheme S
$$\begin{align*}\widetilde{\mathscr{A}^{\mathrm{spl}}}(S) = \{(\underline{A},\underline{\mathscr{F}_{\bullet}}, \underline{\tau} = \{{\tau}_{i,j}^l\})\},\end{align*}$$
where
$(\underline {A},\underline {{\mathscr {F}}_{\bullet }})$
is an S-point of
$\mathscr {A}^{\mathrm {spl}}$
and for each
$i\in I, 1\leq j\leq f_i$
,
$\underline {\tau }$
is a collection of isomorphisms
$$\begin{align*}{\tau}_{i,j}^l: \operatorname{\mathrm{Ker}}({(\pi_i-\sigma_{i,j}^{l}(\pi_i)})|_{\mathcal{H}_{i,j} / \mathscr{F}_{i,j}^{l-1}}) \simeq \Lambda_{i,j}^l \otimes_{{\mathcal{O}}_F} \mathcal{O}_S.\end{align*}$$
By Propositions 5.2 and 9.2 of [Reference Pappas and Rapoport49], when i is of type (AL) or type (C), such an isomorphism exists locally. Moreover, when i is of type (AU), the same proof equally applies.
Let
$\mathbb {M}_{i,j}^l = \mathbb {M}^{\mathrm {loc}}(G_{i,j}^l, \mu _{i,j}^l)$
be the unramified local models over
${\mathcal {O}}_F$
. Then we have the following local model diagram (which is a special case of the local model diagram in Proposition A.8):
where the index
$(i,j,l)$
runs through
$1 \leq i \leq r, 1 \leq j \leq f_i, 1 \leq l \leq e_i $
, the morphism q is smooth and given by
$$\begin{align*}(\underline{A}, \underline{\mathscr{F}_{\bullet}}, \underline{\tau}) \mapsto ({\tau}_{i,j}^l(\mathscr{F}_{i,j}^l / \mathscr{F}_{i,j}^{l-1}))_{i\in I,1\leq j\leq f_i}^{1\leq l \leq e_i},\end{align*}$$
which is
$\prod _{i, j, l} G_{i,j}^l$
-equivariant. The morphism
$\pi $
is the natural forgetful morphism, which is a
$\prod _{i, j, l} G_{i,j}^l$
-torsor.
We have excluded the index of type (AR), so the right-hand side of the local model diagram is a product of unramified local models with hyperspecial level, which is known to be smooth. This shows that
$\mathscr {A}^{\mathrm {spl}}$
is smooth over
${\mathcal {O}}_F$
.
Let
${\mathscr {A}}$
be the scheme-theoretic image of the natural morphism
$$\begin{align*}\mathscr{A}^{\mathrm{spl}} \to {\mathscr{A}}^{\operatorname{\mathrm{naive}}} \otimes_{{\mathcal{O}}_E} {\mathcal{O}}_F \to \mathscr{A}^{\operatorname{\mathrm{naive}}}.\end{align*}$$
Then
${\mathscr {A}}$
is flat over
${\mathcal {O}}_E$
. Moreover,
${\mathscr {A}}$
admits a local model diagram, cf. Proposition A.7. Thus under the condition of Proposition 2.3, the morphism
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}}\longrightarrow{\mathscr{A}}\end{align*}$$
is a resolution of singularities. Note that in this case, the associated parahoric subgroup
$K_p={\mathcal {G}}(\mathbb {Z}_p)$
is very special in the sense of [Reference Zhu71] Definition 6.1. The purpose of this paper is to show that in our ramified setting, the smooth splitting model
${\mathscr {A}}^{\mathrm {spl}}$
admits many nice properties as in the unramified setting.
Recall that the Hodge cocharacter
$\mu : \mathbb {G}_{m, F}\rightarrow G_F$
defines a parabolic subgroup
$P_\mu =\{g\in G_F\,|\,\lim _{t\rightarrow 0}\mu (t)g\mu (t)^{-1}\,\textrm {exists}\}$
over F in the usual way. For any
$(V,\eta )\in \mathrm {Rep}_FP_\mu $
, we have the associated automorphic vector bundle
$\mathcal {V}$
over
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}} \otimes_{{\mathcal{O}}_F} F \simeq \mathscr{A}^{\operatorname{\mathrm{naive}}} \otimes_{{\mathcal{O}}_E} F\simeq {\mathscr{A}}\otimes_{{\mathcal{O}}_E}F,\end{align*}$$
cf. [Reference Milne41]. Since G is split over F, we have a canonical reductive model
${\mathcal {O}}_F$
, which by abuse of notation we still denote by G (the precise meaning of the notation G will be clear from the context; sometimes as in the last subsection we denote it by
${\mathcal {G}}^{\mathrm {spl}}$
). Moreover, the parabolic
$P_\mu $
extends to a parabolic subgroup over
${\mathcal {O}}_F$
, which by abuse of notation we still denote by
$P_\mu $
, and
$(V,\eta )$
naturally extends to a representation of
$P_\mu $
over
${\mathcal {O}}_F$
. In general, it is hard to extend
$\mathcal {V}$
to a vector bundle on
${\mathscr {A}}_{{\mathcal {O}}_F}$
. Nevertheless, we have
Corollary 2.4.
$\mathcal {V}$
extends canonically to a vector bundle on
${\mathscr {A}}^{\mathrm {spl}}$
.
Proof. Note that the integral flag variety over
${\mathcal {O}}_F$
is
$\mathscr {F}\ell (G,\mu )=G/P_\mu =\prod _{i,j,l}\mathbb {M}_{i,j}^l $
. The diagram in the proof of the above proposition is the diagram of schemes over
${\mathcal {O}}_F$
Then we can construct an integral canonical model of
$\mathcal {V}$
over
${\mathscr {A}}^{\mathrm {spl}}$
by using this diagram as in [Reference Milne41].
By abuse of notation, we still denote by
$\mathcal {V}$
the integral automorphic vector bundle over
${\mathscr {A}}^{\mathrm {spl}}$
. We discuss the example of the standard representation
$\Lambda ^{\mathrm {spl}}$
. Let
$(A^{\textrm {univ}},\lambda ,\iota )$
be the universal abelian scheme over
${\mathscr {A}}^{\mathrm {spl}}$
and
$\mathcal {H}=H^1_{\operatorname {\mathrm {dR}}}(A^{\textrm {univ}}/{\mathscr {A}}^{\mathrm {spl}})$
. Then as before we have decompositions
$\mathcal {H}=\bigoplus _i\mathcal {H}_i^{m_i}, \mathcal {H}_i=\bigoplus _j\mathcal {H}_{i,j}$
. We have also the universal splitting structure
$\underline {{\mathscr {F}}_{\bullet }}$
on
$\mathcal {H}$
. For each
$i,j,l$
, we define
$$\begin{align*}\mathcal{M}_{i,j}^l=\operatorname{\mathrm{Ker}}((\pi_i\otimes 1-1\otimes\sigma_{i,j}^l(\pi_i))|\mathcal{H}_{i,j}/{\mathscr{F}}_{i,j}^{l-1}).\end{align*}$$
Then the automorphic vector bundle over
${\mathscr {A}}^{\mathrm {spl}}$
associated to
$\Lambda ^{\mathrm {spl}}$
is
$$\begin{align*}\mathcal{M}=\bigoplus_i\mathcal{M}_i^{m_i},\quad \mathcal{M}_i=\bigoplus_{j,l}\mathcal{M}_{i,j}^l.\end{align*}$$
3 F-zips with additional structure and Ekedahl-Oort stratification
In this section, we keep our assumption that there is no index of type (AR), so we have a smooth splitting integral model
$\mathscr {A}^{\mathrm {spl}} / {\mathcal {O}}_F$
. We will construct a universal F-zip with additional structure over the special fiber
$\mathscr {A}^{\mathrm {spl}}_0$
of
$\mathscr {A}^{\mathrm {spl}}$
. Then we study some basic properties of the induced Ekedahl-Oort stratification on
$\mathscr {A}^{\mathrm {spl}}_0$
.
3.1 F-zips and G-zips
We first recall the notion of F-zips ([Reference Moonen and Wedhorn43]). For any
$\mathbb {F}_p$
-scheme S and any object M over S, we write
$M^{(p)}$
for the pullback of M under the absolute Frobenius of S.
Definition 3.1. Let S be a scheme over
$\mathbb {F}_p$
and
$\sigma : S \to S$
be the absolute Frobenius of S. An F-zip over S is a tuple
$\underline {M} = (M, C^\bullet , D_{\bullet }, \varphi _{\bullet })$
where
-
• M is a locally free sheaf of finite rank on S;
-
•
$C^\bullet = (C^i)_{i \in \mathbb {Z}}$
is a descending filtration on M and each
$C^i$
is a locally free
${\mathcal {O}}_S$
-module; -
•
$D_{\bullet } = (D_i)_{i \in \mathbb {Z}}$
is an ascending filtration on M and each
$D_i$
is a locally free
${\mathcal {O}}_S$
-module; -
•
$\varphi _{\bullet } = (\varphi _i)_{i \in \mathbb {Z}}$
and for each i,
$\varphi _i: C^i /C^{i+1} \to D_i / D_{i-1}$
is a
$\sigma $
-linear map whose linearization is an isomorphism.
$$\begin{align*}\varphi_i^{\mathrm{lin}}: (C^i / C^{i+1})^{(p)} \to D_i / D_{i-1}\end{align*}$$
Next we briefly review the notion of G-zips and the theory of G-zip stacks ([Reference Pink, Wedhorn and Ziegler53, Reference Pink, Wedhorn and Ziegler54]) for later use in this section. Let G be a connected reductive group over
$\mathbb {F}_p$
, and
$\chi $
be a cocharacter of G defined over a finite field
$\kappa |\mathbb {F}_p$
. Let
$P_+$
(resp.
$P_-$
) be the parabolic subgroup of
$G_\kappa $
such that its Lie algebra is the sum of spaces with non-negative weights (resp. nonpositive weights) in
$\operatorname {\mathrm {Lie}}(G_\kappa )$
under
$\operatorname {\mathrm {Ad}} \circ \chi $
. We will also write
$U_+$
(resp.
$U_-$
) for the unipotent radical of
$P_+$
(resp.
$P_-$
). Let L be the common Levi subgroup of
$P_+$
and
$P_-$
.
Definition 3.2. Let S be a scheme over
$\kappa $
.
-
(1) A G-zip of type
$\chi $
over S is a tuple
$\underline {I} = (I,I_+,I_-,\iota )$
consisting of-
• a right
$G_\kappa $
-torsor I over S, -
• a right
$P_+$
-torsor
$I_+ \subset I$
, -
• a right
$P_{-}^{(p)}$
-torsor
$I_{-} \subset I$
, -
• an isomorphism of
$L^{(p)}$
-torsors
$\iota : I_{+}^{(p)} / U_+^{(p)} \to I_{-} / U_-^{(p)} $
.
-
-
(2) A morphism
$(I,I_+,I_-,\iota ) \to (I',I^{\prime }_+,I^{\prime }_-,\iota ')$
of G-zips of type
$\chi $
over S consists of equivariant morphisms
$I \to I'$
and
$I_\pm \to I^{\prime }_\pm $
that are compatible with inclusions and the isomorphism
$\iota $
and
$\iota '$
.
One can prove that the category of F-zips of rank n is equivalent to the category of
$\operatorname {\mathrm {GL}}_n$
-zips, see [Reference Pink, Wedhorn and Ziegler54] 8A. More generally, for a classical group G, a G-zip is equivalent to the F-zip associated to its natural faithful representation, together with the additional structure corresponding to the linear algebraic data defining the group, cf. [Reference Pink, Wedhorn and Ziegler54] section 8.
The category of G-zips of type
$\chi $
over S will be denoted by
${G}\text {-}\mathrm {Zip}^{\chi }_\kappa (S)$
. This defines a category fibered in groupoids
${G}\text {-}\mathrm {Zip}^{\chi }_\kappa $
over
$\kappa $
.
Theorem 3.3 [Reference Pink, Wedhorn and Ziegler54].
The fibered category
${G}\text {-}\mathrm {Zip}^{\chi }_\kappa $
is a smooth algebraic stack of dimension 0 over
$\kappa $
.
Denote by
$\operatorname {\mathrm {Frob}}_p:L \to L^{(p)}, \, l\mapsto l^{(p)}$
the relative Frobenius of L, and define
$E_{G,\chi }$
by the fiber product
Then we have
$$\begin{align*}E_{G,\chi} = \{(p_+ := l u_+, p_- := l^{(p)} u_-) \,|\, l \in L, u_+ \in U_+, u_- \in U_-^{(p)}\}.\end{align*}$$
It acts on
$G_\kappa $
from the left-hand side as follows: for
$(p_+, p_-) \in E_{G,\chi }(S)$
and
$g \in G_\kappa (S)$
, set
$(p_+, p_-) \cdot g := p_+ g p_-^{-1}$
.
Theorem 3.4 [Reference Pink, Wedhorn and Ziegler54].
We have an isomorphism of algebraic stacks
$[E_{G,\chi } \backslash G_\kappa ] \simeq {G}\text {-}\mathrm {Zip}^{\chi }_\kappa $
.
Let
$B \subset G$
be a Borel subgroup and
$T \subset B$
a maximal torus. Let
$W := W(B,T)$
be the absolute Weyl group, and
$I := I(B,T)$
be the set of simple reflections defined by B. Let
$J \subset I$
be the simple roots whose inverse are roots of
$P_+$
. Let
$W_J$
be the subgroup of W generated by J, and
$^J W$
be the set of elements w such that w is the element of minimal length in some coset
$W_J w'$
. By [Reference Pink, Wedhorn and Ziegler53] section 6, there is a partial order
$\preceq $
on
$^J W$
. Let
$k=\overline {\kappa }$
be an algebraic closure of
$\kappa $
, and
$\varphi : W\rightarrow W$
the isomorphism induced from the Frobenius of G. There is a distinguished element
$x\in W$
satisfying certain technical conditions, see [Reference Pink, Wedhorn and Ziegler53] 12.2.
Theorem 3.5 [Reference Pink, Wedhorn and Ziegler53].
For
$w \in {}^J W$
, and
$(B', T')$
a Borel pair of
$G_k$
such that
$T' \subset L_k$
and
$B' \subset P_{-,k}^{(p)}$
, let
$g, \dot {w} \in N_{G_k}(T')$
be the representative of
$\varphi ^{-1}(x)$
and w respectively, and
$G_w \subset G_k$
the
$E_{G,\chi }$
-orbit of
$g B' \dot {w} B'$
. Then
-
(1) The orbit
$G_w$
does not depend on the choices of
$\dot {w}, T', B'$
or g. -
(2) The orbit
$G_w$
is a locally closed smooth subvariety of
$G_k$
. Its dimension is
$\dim (P)+l(w)$
. Moreover,
$G_w$
consists of only one
$E_{G,\chi }$
-orbit. -
(3) Denote by
$|[E_{G,\chi } \backslash G_\kappa ] \otimes k|$
the topological space of
$[E_{G,\chi } \backslash G_\kappa ] \otimes k$
, and
$^J W$
the topological space induced by the partial order
$\preceq $
. Then the association
$w \mapsto G_w$
induces a homeomorphism
$^J W \simeq |[E_{G,\chi } \backslash G_\kappa ]|$
.
In the following, we will apply the above results to the pair
$(G,\chi )=(\mathcal {G}_0^{\mathrm {spl}},\mu )$
constructed in subsection 2.1.
3.2 Construction of the universal
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip on
${\mathscr {A}}^{\mathrm {spl}}_0$
Let
$\kappa $
be the residue field of
${\mathcal {O}}_F$
and
$\sigma $
the absolute Frobenius of
$\kappa $
. We will construct a universal
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip of type
$\mu $
over the special fiber
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}}_0= \mathscr{A}^{\mathrm{spl}} \otimes_{{\mathcal{O}}_F} \kappa\end{align*}$$
of
$\mathscr {A}^{\mathrm {spl}}$
. As in the unramified case, we will first construct a vector bundle
$\mathcal {M}$
over
${\mathscr {A}}^{\mathrm {spl}}_0$
, which can be viewed as a semisimplification of the de Rham cohomology of the universal abelian scheme for the additional structure. The construction of such a vector bundle was already mentioned below [Reference Reduzzi and Xiao56, Corollary 2.10] for Hilbert modular varieties.
For any
$\kappa $
-scheme S,
$\mathscr {A}_0^{\mathrm {spl}}(S)$
classifies the isogeny classes of
$(\underline {A}, \underline {\mathscr {F}_{\bullet }})$
, where
-
(1)
$\underline {A}=(A, \lambda , \iota ,\alpha )$
is an S-point of
$\mathscr {A}^{\operatorname {\mathrm {naive}}}$
. -
(2)
$\underline {\mathscr {F}_{\bullet }}=(\mathscr {F}_{i,j}^l)$
is a splitting structure of
${\mathcal {O}}_F \otimes _{\mathbb {Z}_p} {\mathcal {O}}_S$
-module
$\omega _{A/S}$
. This means: if we write
$\mathcal {H} = \mathcal {H}_{\operatorname {\mathrm {dR}}}^1(A/S)$
, it is an
${\mathcal {O}}_F \otimes {\mathcal {O}}_S$
-module, hence has a decomposition with
$$\begin{align*}\mathcal{H} = \bigoplus_{i\in I} \bigoplus_{j=1}^{f_i} \mathcal{H}_{i,j}^{m_i},\end{align*}$$
$\mathcal {H}_{i,j}$
a locally free
${\mathcal {O}}_S$
-module equipped with a pairing
$\mathcal {H}_{i,j}\times \mathcal {H}_{i,j}\rightarrow {\mathcal {O}}_S$
. Similarly, we have a decomposition
$\omega =\bigoplus _{i\in I}\bigoplus _{j=1}^{f_i}\omega _{i,j}^{m_i}$
. For each
$i\in I,1\leq j\leq f_i$
, the splitting structure is a filtration of locally direct
${\mathcal {O}}_S$
-factors of
$\omega _{i,j}$
: with
$$\begin{align*}0 = \mathscr{F}_{i,j}^0 \subset \mathscr{F}_{i,j}^1 \subset \cdots \subset \mathscr{F}_{i,j}^{e_i} = {\omega_{i,j}} \subset \mathcal{H}_{i,j}\end{align*}$$
${\mathcal {O}}_{F_i}/ (p) \simeq \kappa _i[T]/(T^{e_i}) = \kappa _i[\varepsilon _i]$
-action, such that
-
(a)
$\kappa _i$
acts on
$\mathscr {F}_{i,j}^l$
by
$\sigma _{i,j}: \mathcal {O}_{F_i^{\mathrm {ur}}} \to \kappa $
. -
(b) For each
$1 \leq l \leq e_i$
,
$\varepsilon _i \mathscr {F}_{i,j}^l \subset \mathscr {F}_{i,j}^{l-1}$
. -
(c) For each
$1 \leq l \leq e_i$
,
$\mathscr {F}_{i,j}^l / \mathscr {F}_{i,j}^{l-1}$
is locally free of rank
$d_{i,j}^l$
. -
(d) For each
$1 \leq l \leq e_i$
,
$\mathscr {F}_{i,j}^{l,\perp }=(\varepsilon _i^{e_i-l})^{-1}\mathscr {F}_{i,j}^l$
.
-
Let
$S=\mathscr {A}_0^{\mathrm {spl}}$
and
$\underline {A}$
be the universal abelian scheme over S. For each triple
$i,j,l$
, we define
$$\begin{align*}\mathcal{M}_{i,j}^l := \varepsilon_i^{-1}\mathscr{F}_{i,j}^{l-1} / \mathscr{F}_{i,j}^{l-1}.\end{align*}$$
Note that each
$\mathcal {M}_{i,j}^l$
is a locally free
${\mathcal {O}}_S$
-module of rank
$2d_i$
. As in the description below Definition 2.1, in fact we have some reduced description for
$\mathcal {M}_{i,j}^l$
according to the type of i, which we leave to the reader. Now we write
$$\begin{align*}\mathcal{M} = \bigoplus_{i\in I} {\mathcal{M}}_i^{m_i},\quad {\mathcal{M}}_i= \bigoplus_{l=1}^{e_i} \bigoplus_{j=1}^{f_i} \mathcal{M}_{i,j}^l,\end{align*}$$
then each
$\mathcal {M}_{i,j}^l$
is locally isomorphic to
$\Lambda _{i,j}^l \otimes _{{\mathcal {O}}_F} {\mathcal {O}}_S$
. First fix
$i \in I$
and
$1\leq j \leq f_i$
. For each
$1 \leq l \leq e_i$
, we have two natural maps:
-
(1) If
$l \neq 1$
, we have a natural map: which is an
$$\begin{align*}V_{i,j}^l: \mathcal{M}_{i,j}^l \to \mathcal{M}_{i,j}^{l-1},\quad x \mapsto \varepsilon_i x,\end{align*}$$
${\mathcal {O}}_S$
-linear morphism. On the other side, the injection
$\varepsilon _i^{-1}\mathscr {F}_{i,j}^{l-2} \hookrightarrow \varepsilon _i^{-1}\mathscr {F}_{i,j}^{l-1}$
induces an
${\mathcal {O}}_S$
-linear morphism
$$\begin{align*}F_{i,j}^l: \mathcal{M}_{i,j}^{l-1} \to \mathcal{M}_{i,j}^{l}.\end{align*}$$
-
(2) If
$l=1$
, let
$V_{i,j}: \mathcal {H}_{i,j} \to \mathcal {H}_{i,j-1}$
be the Verschiebung morphism and
$F_{i,j}: \mathcal {H}_{i,j-1} \to \mathcal {H}_{i,j}$
the Frobenius morphism. The map
$V_{i,j}$
induces a natural map which is
$$\begin{align*}V_{i,j}^1:\mathcal{M}_{i,j}^1 \to \mathcal{M}_{i,j-1}^{e_i},\quad x \mapsto V_{i,j}(\varepsilon_i^{1-e_i}(x)),\end{align*}$$
$\sigma ^{-1}$
-linear. Similarly,
$F_{i,j}$
induces a
$\sigma $
-linear map
$$\begin{align*}F_{i,j}^1: \mathcal{M}_{i,j-1}^{e_i} \to \mathcal{M}_{i,j}^1,\quad x \mapsto F_{i,j}(x).\end{align*}$$
Now for each
$1\leq l\leq e_i$
, define
$$\begin{align*}\mathcal{M}_i^l := \bigoplus_{j=1}^{f_i}\mathcal{M}_{i,j}^l, \quad \Lambda_i^l := \bigoplus_{j=1}^{f_i} \Lambda_{i,j}^l.\end{align*}$$
Each
${\mathcal {M}}_{i}^l$
is a locally free
${\mathcal {O}}_S[\varepsilon _i]$
-module with a
$\kappa _i$
-action, and we have locally an isomorphism
$$\begin{align*}{\mathcal{M}}_{i}^l \simeq \Lambda_i^l \otimes_{{\mathcal{O}}_F} {\mathcal{O}}_S.\end{align*}$$
(Note that the lattice
$\Lambda _{i,j}^l$
is denoted by
$\Xi _{i,j}^l$
in [Reference Pappas and Rapoport49, Proposition 5.2.]) We also have locally an isomorphism
$$\begin{align*}{\mathcal{M}}_{i} = \bigoplus_{l=1}^{e_i} {\mathcal{M}}_{i}^l \simeq \bigoplus_{l=1 }^{e_i} \Lambda_{i,0}^l\otimes{\mathcal{O}}_S= \Lambda_{i,0}^{\mathrm{spl}}\otimes{\mathcal{O}}_S.\end{align*}$$
Each
${\mathcal {M}}_i$
is a locally free
${\mathcal {O}}_S$
-module of rank
$2e_i f_i d_i$
. For each
$i, l$
, let
$F_i^l=\bigoplus _j F_{i,j}^l$
and
$V_i^l=\bigoplus _j V_{i,j}^l$
. We have constructed the following linear morphisms:
and semilinear morphisms (
$F_i^{1}$
is
$\sigma $
-linear and
$V_i^{1}$
is
$\sigma ^{-1}$
-linear)
Lemma 3.6. There is a canonical isomorphism
$g_i: {\mathcal {M}}^1_{i} \to {\mathcal {M}}^1_i$
sending
$\operatorname {\mathrm {Ker}}(V_i^1)$
to
$\operatorname {\mathrm {Im}}(F_i^1)$
.
Proof. We can reduce to the case
$S=\operatorname {\mathrm {Spec}}\,R$
for a ring R over
$\kappa $
. For
$e_i=1$
, we have
$F_i^1 = \operatorname {\mathrm {Frob}}, V_i^1 = \operatorname {\mathrm {Ver}}$
, so we can assume that
$e_i \geq 2$
. Note that
$$\begin{align*}\operatorname{\mathrm{Ker}}(V_{i,j}^1) = \varepsilon_i^{e_i-1} \operatorname{\mathrm{Ver}}^{-1}({\mathscr{F}}_{i,j}^{e_i}), \quad \operatorname{\mathrm{Im}}(F_{i,j}^1) = \operatorname{\mathrm{Frob}}({\mathscr{F}}_{i,j}^{e_i}).\end{align*}$$
For each j, fix an isomorphism
${\mathcal {H}}_{i,j} \simeq R[\varepsilon _i]^{2d_i}$
and lift it to
$\widetilde {{\mathcal {H}}}_{i,j} = R[[t]]^{2d_i}$
such that
$\widetilde {{\mathcal {H}}}_{i,j} / (t^{e_i}) = {\mathcal {H}}_{i,j}$
. For each
${\mathscr {F}}_{i,j}^l \subset {\mathcal {H}}_{i,j}$
, let
$\widetilde {{\mathscr {F}}}_{i,j}^l$
be its lifting in
$\widetilde {{\mathcal {H}}}_{i,j}$
. One can lift the Frobenius and Verschiebung morphisms of
${\mathcal {H}}_i$
to injections of
$\widetilde {{\mathcal {H}}}_{i}$
, such that
$$\begin{align*}\operatorname{\mathrm{Ver}}(\widetilde{{\mathcal{H}}}_{i,j}) = \widetilde{{\mathscr{F}}}_{i,j-1}^{e_i}, \quad \operatorname{\mathrm{Frob}}(\widetilde{{\mathscr{F}}}_{i,j-1}^{e_i}) = t^{e_i}\widetilde{{\mathcal{H}}}_{i,j}.\end{align*}$$
This gives the following isomorphism:
Such an isomorphism sends the lifting of
$\operatorname {\mathrm {Ker}}(V_{i,j}^1)$
to the lifting of
$\operatorname {\mathrm {Im}}(F_{i,j}^1)$
. After modding out by
$(t^{e_i})$
of the above isomorphism, we get an isomorphism
$$\begin{align*}g_{i}: {\mathcal{M}}_i^1 \to {\mathcal{M}}_i^1\end{align*}$$
sending
$\operatorname {\mathrm {Ker}}(V_{i,j}^1)$
to
$\operatorname {\mathrm {Im}}(F_{i,j}^1)$
.
Lemma 3.7. For each integer
$2\leq l\leq e_i$
, we have the following identities:
$$\begin{align*}\operatorname{\mathrm{Im}}(F_i^l) = \operatorname{\mathrm{Ker}}(V_i^l), \quad \operatorname{\mathrm{Ker}}(F_i^l) = \operatorname{\mathrm{Im}}(V_i^l).\end{align*}$$
Moreover, we have
$$\begin{align*}\operatorname{\mathrm{rank}}(\operatorname{\mathrm{Ker}}(V_{i,j}^l)) = d_{i,j}^l\quad \textrm{and }\quad \operatorname{\mathrm{rank}}(\operatorname{\mathrm{Ker}}(F_{i,j}^l)) = d_i - d_{i,j}^l.\end{align*}$$
Proof. By our definition, for each
$l \geq 2$
, we have
$$\begin{align*}\operatorname{\mathrm{Ker}}(F_{i,j}^l) = \operatorname{\mathrm{Im}}(V_{i,j}^l) = {\mathscr{F}}_{i,j}^l, \quad \operatorname{\mathrm{Im}}(F_{i,j}^l) = \operatorname{\mathrm{Ker}}(V_{i,j}^l) = \varepsilon_i^{-1} {\mathscr{F}}_{i,j}^{l-2}. \end{align*}$$
The rank of
${\mathscr {F}}_{i,j}^l / {\mathscr {F}}_{i,j}^{l-1}$
is
$d_{i,j}^l$
by the definition of splitting structures.
Recall that
${\mathcal {M}}_{i,j}^l = \varepsilon _i^{-1} {\mathscr {F}}_{i,j}^{l-1} / {\mathscr {F}}_{i,j}^{l-1}\simeq {\mathscr {F}}_{i,j}^{2e_i-l+1}/\varepsilon _i{\mathscr {F}}_{i,j}^{2e_i-l+1}$
. The symplectic pairing on
${\mathscr {F}}_{i,j}^{2e_i-l+1}\subset {\mathcal {H}}_{i,j}$
induces a pairing on
${\mathcal {M}}_{i,j}^l$
.
Recall the group
${\mathcal {G}}_0^{\mathrm {spl}}$
constructed in 2.1.4 as a similitude group with respect to the vector space
$\Lambda _{0}^{\mathrm {spl}}$
with its symplectic form
$\psi $
. Recall that we have introduced a cocharacter
$$\begin{align*}\mu = \prod_{i, j, l} \mu_{i, j}^{l}: {\mathbb{G}}_{m,\kappa} \to \mathcal{G}^{\mathrm{spl}}_{0,\kappa}.\end{align*}$$
Such a datum gives the parabolic subgroups
$P_+, P_-$
of
${\mathcal {G}}_{\kappa }^{\mathrm {spl}}$
and corresponding unipotent groups
$U_+, U_-$
, and the common Levi subgroup
$L = P_+ \cap P_-$
as in the previous subsection. The cocharacter
$\mu $
induces a standard F-zip
$$\begin{align*}(\Lambda_{0}^{\mathrm{spl}}, C_0, D_0, \varphi_{0,\bullet}).\end{align*}$$
Moreover, the above construction gives an F-zip
$$\begin{align*}({\mathcal{M}} = \bigoplus_i {\mathcal{M}}_i^{m_i}, C = \bigoplus_i \operatorname{\mathrm{Ker}}(F_i)^{m_i}, D = \bigoplus_i \operatorname{\mathrm{Ker}}(V_i)^{m_i}, \varphi_{\bullet})\end{align*}$$
over
${\mathscr {A}}_0^{\mathrm {spl}}$
, equipped with a natural symplectic form
$\psi $
and an
${\mathcal {O}}_B$
-action with the natural isomorphisms
$$\begin{align*}\varphi_{\bullet}: {\mathcal{M}} / C \simeq D^\phi, \quad C \simeq ({\mathcal{M}} / D)^\phi,\end{align*}$$
where
$\phi = \prod _i \phi _i: {\mathcal {G}}_0^{\mathrm {spl}} \to {\mathcal {G}}_0^{\mathrm {spl}}$
is the group isomorphism given by
$$\begin{align*}\phi_i: {\mathcal{G}}_{i,0}^{\mathrm{spl}} \to {\mathcal{G}}_{i,0}^{\mathrm{spl}}, \quad (x_1, \dots, x_{e_i}) \mapsto (x_2, \dots, x_{e_i}, x_1^p),\end{align*}$$
and
$D^\phi $
is the same module D but with
${\mathcal {G}}_0^{\mathrm {spl}}$
-action twisted by
$\phi $
. The subvector bundles C and D are totally isotropic with respect to the symplectic form
$\psi $
on
${\mathcal {M}}$
.
Proposition 3.8. We have
-
(1)
$I := {\underline {Isom}}(({\mathcal {M}}, \psi ), (\Lambda _{0}^{\mathrm {spl}}, \psi ))$
is a
${\mathcal {G}}_{0}^{\mathrm {spl}}$
-torsor over
${\mathscr {A}}_0^{\mathrm {spl}}$
. -
(2)
$I_{+} := {\underline {Isom}}({\mathcal {M}} \supset C \supset 0, \Lambda _{0}^{\mathrm {spl}} \supset C_0 \supset 0)$
is a
$P_+$
-torsor over
${\mathscr {A}}_0^{\mathrm {spl}}$
. -
(3)
$I_{-} := {\underline {Isom}}({\mathcal {M}}\supset D \supset 0, \Lambda _{0}^{\mathrm {spl}} \supset D_0 \supset 0)$
is a
$P_-^{\phi }$
-torsor over
${\mathscr {A}}_0^{\mathrm {spl}}$
. -
(4) We have an
$L^{\phi }$
-equivariant isomorphism
$\iota : (I_+ / U_+)^\phi \simeq I_- / U_-^\phi $
.
In the above, all the isomorphisms preserve the natural additional structure.
Proof. By the proofs of Propositions 2.3 and A.8, there is a local model diagram
where
$M^{{\mathrm {loc}}}$
is the special fiber of
$\mathbb {M}^{\mathrm {loc}}(\mathcal {G}^{\mathrm {spl}},\mu )$
, q sends
$(x = (\underline {A},\underline {{\mathscr {F}}}_{\bullet }), \tau :{\mathcal {M}}_x \simeq \Lambda ^{\mathrm {spl}}_0)$
to
$\tau ({\mathcal {M}}_x \supset C_x) \in M^{{\mathrm {loc}}} = {\mathcal {G}}_0^{\mathrm {spl}} / P_+$
. By the same arguments as in [Reference Shen, Yu and Zhang59, §3.4], we have
-
•
$I = \widetilde {{\mathscr {A}}}^{\mathrm {spl}}_0$
is a
${\mathcal {G}}_{0}^{\mathrm {spl}}$
-torsor; -
•
$I_+ = q^{-1}(\Lambda _0^{\mathrm {spl}} \supset C_0)$
is a
$P_+$
-torsor;
Recall the forgetful map
${\mathscr {A}}^{\mathrm {spl}}_0\rightarrow {\mathscr {A}}_0$
. There is a conjugate local model diagram for
${\mathscr {A}}_0$
:
where
$M^{{\mathrm {loc}},c}({\mathcal {G}}_0, \mu )$
classifies the conjugate filtration of
${\mathscr {A}}_0$
defined in [Reference Shen, Yu and Zhang59] and
$q^c$
is a smooth morphism (same as [Reference Shen, Yu and Zhang59, Theorem 3.4.2]) sending points of
$\widetilde {{\mathscr {A}}}_0$
to corresponding conjugate filtration. Let
$$ \begin{align*}M^{\mathrm{spl}, c}({\mathcal{G}}_0, \mu) \to M^{{\mathrm{loc}}, c}({\mathcal{G}}_0, \mu)\end{align*} $$
be the scheme over k classifying the splitting structures of
$M^{{\mathrm {loc}}, c}({\mathcal {G}}_0, \mu )$
. The pull-back of the morphism
$q^c$
gives the conjugate splitting local model diagram
By the previous method of constructing local model diagram of splitting models, there is a local model diagram:
where
$M^{{\mathrm {loc}}, c}:= M^{{\mathrm {loc}}, c}({\mathcal {G}}_0^{\mathrm {spl}}, \mu )$
and
$q^c$
is a
${\mathcal {G}}_0^{\mathrm {spl}}$
-equivariant smooth morphism sending
$(x = (\underline {A},\underline {{\mathscr {F}}_{\bullet }}), \tau :{\mathcal {M}}_x \simeq \Lambda ^{\mathrm {spl}}_0)$
to
$\tau (D_x \subset {\mathcal {M}}_x) \in M^{{\mathrm {loc}},c} := {\mathcal {G}}_0^{\mathrm {spl}} / P_-^{\phi }$
. Combining these diagrams we have
-
•
$I_- := q^{c,-1}(D_0 \subset \Lambda _0^{\mathrm {spl}})$
is a
$P_-^{\phi }$
-torsor. This follows from the same argument of
$I_+$
using the conjugate local model diagram; -
• There is an
$L^{\phi }$
-equivariant isomorphism
$\iota : (I_+ / U_+)^{\phi } \simeq I_- / U_-^{\phi }$
. This follows from Lemma 3.6 and Lemma 3.7.
Let
$\phi ' = \prod _i \phi ^{\prime }_i$
be the group isomorphism given by
$$\begin{align*}\phi^{\prime}_i: {\mathcal{G}}_{i,0}^{\mathrm{spl}} \to {\mathcal{G}}_{i,0}^{\mathrm{spl}}, \quad (x_1, \dots, x_{e_i}) \mapsto (x_{e_i}, x_1^p, \dots, x_{e_i-1}^p).\end{align*}$$
Then we have
$\phi \cdot \phi ' = \phi ' \cdot \phi = \sigma $
, so
$I_-^{\phi '}$
is a
$P_-^{(p)}$
-torsor and
$$\begin{align*}\iota^{\phi'}: (I_+ / U_+)^{(p)} \simeq I_-^{\phi'} / U_-^{(p)}\end{align*}$$
is an
$L^{(p)}$
-equivariant isomorphism. This is the universal
$\mathcal {G}_0^{\mathrm {spl}}$
-zip of type
$\mu $
over
$\mathscr {A}_0^{\mathrm {spl}}$
, i.e., there is a morphism of algebraic stacks over
$\kappa $
:
$$\begin{align*}\zeta: \mathscr{A}_0^{\mathrm{spl}} \to {\mathcal{G}_0^{\mathrm{spl}}}\text{-}\mathrm{Zip}^{\mu}_\kappa.\end{align*}$$
Definition 3.9. The fibers of
$\zeta $
are called the Ekedahl-Oort strata of
$\mathscr {A}^{\mathrm {spl}}_0$
.
Note that for each
$1\leq i\leq r$
, by construction we have in fact a universal
${\mathcal {G}}_{i,0}^{\mathrm {spl}}$
-zip of type
$\mu _i$
over
$\mathscr {A}^{\mathrm {spl}}_0$
, thus a morphism
$$\begin{align*}\zeta_i: \mathscr{A}_0^{\mathrm{spl}} \to {\mathcal{G}_{i,0}^{\mathrm{spl}}}\text{-}\mathrm{Zip}^{\mu_i}_\kappa.\end{align*}$$
Via the inclusion
$\mathcal {G}_0^{\mathrm {spl}}\subset \prod _i{\mathcal {G}}_{i,0}^{\mathrm {spl}}$
, the universal
$\mathcal {G}_0^{\mathrm {spl}}$
-zip of type
$\mu $
over
$\mathscr {A}_0^{\mathrm {spl}}$
induces a
$\prod _i{\mathcal {G}}_{i,0}^{\mathrm {spl}}$
-zip of type
$\prod _i\mu _i$
, which is isomorphic to the product of all the
${\mathcal {G}}_{i,0}^{\mathrm {spl}}$
-zip of type
$\mu _i$
.
3.3 Smoothness of
$\zeta $
The dimension formula, closure relation, and smoothness of the EO (Ekedahl-Oort) strata follow from the following proposition.
Proposition 3.10. The morphism
$\zeta : \mathscr {A}_0^{\mathrm {spl}} \to {\mathcal {G}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_\kappa $
is smooth.
Proof. Let k be the algebraic closure of
$\kappa $
. Consider the following cartesian diagram
The smoothness of
$\zeta $
is equivalent to the smoothness of
$\zeta ^\#$
, which is also equivalent to the surjectivity of the induced map on tangent spaces at points of
$\mathscr {A}^{{\mathrm {spl}}\#}(k)$
.
Recall
${\mathcal {G}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_\kappa \simeq [E \backslash \mathcal {G}_0^{\mathrm {spl}}]$
. Let
$x^\#$
be a closed point of
$\mathscr {A}_k^{\mathrm {spl}}$
with image x in
$\mathscr {A}_k^{\mathrm {spl}}$
. Let A be the complete local ring of
$\mathscr {A}_k^{\mathrm {spl}}$
at x. Consider the cartesian diagram
The morphism
$X \to \operatorname {\mathrm {Spec}}\,A$
is a trivial E-torsor isomorphic to
$\underline {I}_{u g}$
for an A-point
$u g$
of
$\mathcal {G}^{\mathrm {spl}}$
. Let
$U_- \subset \mathcal {G}^{\mathrm {spl}}_k$
be the opposite unipotent subgroup determined by
$\mu $
, then A is isomorphic to the complete local ring of
$U_-$
at identity. The trivialization induces an isomorphism and translates
$\alpha $
into the morphism
$\beta : \operatorname {\mathrm {Spec}}\,A \times _k E_k \to \mathcal {G}^{\mathrm {spl}}_k$
given by for any k-scheme T, on T-points
$\beta : (u,l,u_+,u_-) \mapsto l u_+ u g (l^{(p)}u_-)^{-1}$
. Now the same method of the last paragraph of [Reference Zhang70, Theorem 4.1.2] shows that the map on the tangent space at x is surjective.
3.4 Nonemptiness of EO strata
Recall that we have natural morphisms over
$\kappa $
:
$$\begin{align*}{\mathscr{A}}_{0}^{\mathrm{spl}}\rightarrow {\mathscr{A}}_{0}\rightarrow{\mathscr{A}}_{0}^{\operatorname{\mathrm{naive}}}.\end{align*}$$
In the following we work over
$k=\overline {\kappa }$
. Although we are primarily interested in the geometry of EO strata of
${\mathscr {A}}_k^{\mathrm {spl}}$
, sometimes it would be helpful to study the geometry of
${\mathscr {A}}_k$
together. On
${\mathscr {A}}_{k}^{\operatorname {\mathrm {naive}}}$
, there is a KR (Kottwitz-Rapoport) stratification given by the isomorphism class of
$\omega _{A/S}$
, cf. [Reference Hartwig23]. By [Reference Pappas and Rapoport49, Reference Levin40, Reference Haines and Richarz21], there is also a KR stratification
$$\begin{align*}{\mathscr{A}}_k=\coprod_{w\in\operatorname{\mathrm{Adm}}(\mu)_{K}}{\mathscr{A}}_k^w\end{align*}$$
indexed by the
$\mu $
-admissible set: let
$K=K_p=\mathcal {G}(\mathbb {Z}_p)$
and
$\operatorname {\mathrm {Adm}}(\mu )_{K}$
be the
$\mu $
-admissible set of level K as introduced in [Reference He and Rapoport25], which is the partially ordered set of all KR types of level K. By the discussions in 2.1.3, we have a decomposition
$K=\prod _{i\in I}K_i$
and thus
$\operatorname {\mathrm {Adm}}(\mu )_{K}=\prod _{i\in I}\operatorname {\mathrm {Adm}}(\mu _i)_{K_i}$
. We also have an EKOR (Ekedahl-Kottwitz-Oort-Rapoport) stratification of
$\mathscr {A}_k$
, which is a refinement of the KR stratification, such that for each
$w\in \operatorname {\mathrm {Adm}}(\mu )_{K}$
, we have a morphism of algebraic stacks
$$\begin{align*}\zeta_w: \mathscr{A}_k^w\rightarrow {\mathcal{G}}_0^{\operatorname{\mathrm{rdt}}}\textrm{-Zip}^{J_w},\end{align*}$$
see subsections A.3 and A.4 in the Appendix for more details. If
$w=(w_i)\in \prod _{i\in I}\operatorname {\mathrm {Adm}}(\mu _i)_{K_i}$
, for each i, we have in fact a morphism
$\zeta _{w_i}: \mathscr {A}_k^w\rightarrow {\mathcal {G}}_{0,i}^{\operatorname {\mathrm {rdt}}}\textrm {-Zip}^{J_{w_i}}$
, the i-th component of
$\zeta _w$
.
Proposition 3.11. Let
$\pi : \mathscr {A}^{\mathrm {spl}}_k \to \mathscr {A}_k$
be the natural forgetful morphism. Let
$x\in \mathscr {A}^{\mathrm {spl}}(k)$
and
$y = \pi (x) \in \mathscr {A}(k)$
.
-
• If x is a minimal EO point of
$\mathscr {A}^{\mathrm {spl}}(k)$
(i.e., x lies in the minimal EO stratum), then y is a minimal EKOR point of
$\mathscr {A}(k)$
(i.e., y lies in the minimal EKOR stratum, cf. [Reference Shen, Yu and Zhang59] 1.2.5). -
• If y is a minimal EKOR point, then there exists
$x' \in \pi ^{-1}(y)\subset \mathscr {A}^{\mathrm {spl}}(k)$
such that
$x'$
is a minimal EO point.
Proof. Both the involved
${\mathcal {G}}_0^{\mathrm {spl}}$
-zip and
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zips admit decompositions over the indices i. We proceed according to the type of i.
Case (AL/AU): For each j, write
$\sum _{l} d_{i,j}^l = t_j d_i + s_j$
, where
$0 \leq s_j < d_i$
, and
$$\begin{align*}\omega_{\mathrm{min}} := ({\varepsilon}_i^{e_i - t_j - 1})^{\oplus s_j} \bigoplus ({\varepsilon}_i^{e_i - t_j})^{\oplus d_i - s_j}.\end{align*}$$
Then a point
$y \in {\mathscr {A}}_0$
is a minimal KR point if and only if
$$\begin{align*}\omega_{y,i,j} \simeq \omega_{\mathrm{min}} \bigoplus \omega_{\mathrm{min}}'\end{align*}$$
(cf. [Reference Pappas and Rapoport48] section 3; here
$\omega ^{\prime }_{\mathrm {min}}$
and the splitting structure is determined by such structure on
$\omega _{\mathrm {min}}$
). Assume that
$x = (\underline {A}, \underline {{\mathscr {F}}_{\bullet }})\in \mathscr {A}^{\mathrm {spl}}(k)$
is a minimal EO point and
$y = \pi (x)$
. The minimal condition is equivalent to
-
(1)
${\mathscr {F}}_{i,j}^1 \subset \operatorname {\mathrm {Ker}}(V_{i,j}^1)\quad \textrm {or}\quad \operatorname {\mathrm {Ker}}(V_{i,j}^1) \subset {\mathscr {F}}_{i,j}^1 \subset {\varepsilon }_i^{-1}{\mathscr {F}}_{i,j}^{0}$
. -
(2) For each
$l \geq 2$
,
${\mathscr {F}}_{i,j}^l \subset {\varepsilon }_i^{-1}{\mathscr {F}}_{i,j}^{l-2}\quad \textrm {or}\quad {\varepsilon }_i^{-1}{\mathscr {F}}_{i,j}^{l-2} \subset {\mathscr {F}}_{i,j}^l \subset {\varepsilon }_i^{-1}{\mathscr {F}}_{i,j}^{l-1}$
.
This forces
$$\begin{align*}\omega_{x,i,j} \simeq \omega_{\mathrm{min}} \bigoplus \omega_{\mathrm{min}}',\end{align*}$$
so
$y = \pi (x)$
is a minimal KR point, which is then a minimal EKOR point by condition (1). Conversely, if y is a minimal EKOR point, then by conditions (1) and (2) above, there is a splitting structure
$\underline {{\mathscr {F}}_{\bullet }}$
of y, such that
$x' = (y, \underline {{\mathscr {F}}_{\bullet }})$
minimal.
Case (C): A point
$y \in {\mathscr {A}}_0$
is a minimal KR point if and only if
$\omega _{y,i,j}$
isomorphic to
$$\begin{align*}\omega_{\mathrm{min}} := (({\varepsilon}_i^{\lceil{e_i/2}\rceil}) \bigoplus ({\varepsilon}_i^{\lfloor{e_i/2}\rfloor}))^{\oplus d_i} \subset k[{\varepsilon}_i]^{\oplus 2d_i} .\end{align*}$$
A similar construction as above gives the proof of type (C).
Corollary 3.12. The morphism
$\zeta $
is surjective.
Proof. By Proposition A.15, the EKOR strata of
$\mathscr {A}_0$
are nonempty. Hence, minimal EO points of
${\mathscr {A}}_k^{\mathrm {spl}}$
exist by Proposition 3.11. The smoothness of
$\zeta : {\mathscr {A}}_0^{\mathrm {spl}} \to {{\mathcal {G}}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_\kappa $
plus the fact that its image contains a minimal point imply the surjectivity of
$\zeta $
.
We summarize the above results in a theorem, which describes the expected properties of the Ekedahl-Oort stratification.
Theorem 3.13. We have the following basic properties of the EO strata on smooth splitting models.
-
(1) There is a smooth surjective morphism
of algebraic stacks.
$$\begin{align*}\zeta: {\mathscr{A}}_0^{\mathrm{spl}} \to {{\mathcal{G}}_0^{\mathrm{spl}}}\text{-}\mathrm{Zip}^{\mu}_\kappa\end{align*}$$
-
(2) Let
${}^J W$
be the topological space of
${{\mathcal {G}}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_k$
, and define the EO stratum as
${{\mathscr {A}}_k^{\mathrm {spl},w}} := \zeta ^{-1}(w)$
for each
$w \in {}^J W$
. Then each EO stratum
${\mathscr {A}^{\mathrm {spl},w}_k}$
is a smooth and locally closed subscheme of dimension
$l(w)$
, with the closure relation by the partial order
$\preceq $
, i.e.,
$$\begin{align*}\overline{{\mathscr{A}}_k^{\mathrm{spl},w}} = \coprod_{w' \preceq w} {\mathscr{A}^{\mathrm{spl},w'}_k}, \quad \textrm{ for all } w \in {}^J W.\end{align*}$$
3.5 The
$\mu $
-ordinary locus
Let
$U \subset \mathscr {A}^{\mathrm {spl}}_k$
be the maximal EO stratum, then by Theorem 3.13, U is open dense in
$\mathscr {A}^{\mathrm {spl}}_k$
.
Recall the Kottwitz set
$B(G,\mu )$
(see subsection A.5). The universal abelian scheme with additional structure
$(A,\lambda ,\iota )$
over
${\mathscr {A}}_0^{\mathrm {spl}}$
defines as usual a map
$$\begin{align*}\operatorname{\mathrm{Newt}}: {\mathscr{A}}_0^{\mathrm{spl}}(k)\longrightarrow B(G,\mu),\end{align*}$$
which by construction factors through
${\mathscr {A}}_{0}(k)$
and
${\mathscr {A}}_0^{\operatorname {\mathrm {naive}}}(k)$
.
Definition 3.14. The fibers of
$\operatorname {\mathrm {Newt}}$
define a decomposition of
$\mathscr {A}^{\mathrm {spl}}_k$
, which we call the Newton stratification of
$\mathscr {A}^{\mathrm {spl}}_k$
. Moreover, as G is quasi-split at p, there is a unique maximal Newton stratum in
$\mathscr {A}_k^{\mathrm {spl}}$
, called the
$\mu $
-ordinary locus.
When the group G is unramified over
$\mathbb {Q}_p$
, Moonen [Reference Moonen42] proved that the
$\mu $
-ordinary locus coincides with the maximal EO stratum of
${\mathscr {A}}_k = {\mathscr {A}}_k^{\mathrm {spl}}$
. This fact was generalized to general Hodge-type Shimura varieties with good reduction at p in [Reference Wortmann68]. We will prove that for the ramified PEL-type case, the same result holds for smooth splitting models. As in the last subsection, we will apply the geometry of KR and EKOR stratifications of
${\mathscr {A}}_k$
. Recall that
$\operatorname {\mathrm {Adm}}(\mu )_{K}$
is the
$\mu $
-admissible set of level K, which is the partially ordered set of all KR types of level K. As
$K\subset G({\mathbb {Q}}_p)$
is a special parahoric subgroup, by [Reference Richarz57, Theorem 4.2, Corollary 4.6] the set
$\operatorname {\mathrm {Adm}}(\mu )_{K}$
has a unique maximal element.
Proposition 3.15. Let
$w_0$
be the maximal element of
$\operatorname {\mathrm {Adm}}(\mu )_{K}$
and
$\mathscr {A}_k^{w_0}$
the maximal KR stratum of
$\mathscr {A}_k$
. Then the morphism
$\pi : \mathscr {A}^{\mathrm {spl}}_k \to \mathscr {A}_k$
induces an isomorphism over
$\mathscr {A}_k^{w_0}$
, i.e.,
$\pi : \pi ^{-1}(\mathscr {A}_k^{w_0}) \stackrel {\sim }{\rightarrow } \mathscr {A}_k^{w_0}$
.
Proof. For every
$i,j$
, let
$\{a_{i,j}^l \mid 1 \leq l \leq e_i \}$
be a permutation of
$\{d_{i,j}^l \mid 1 \leq l \leq e_i\}$
such that
$$\begin{align*}a_{i,j}^1 \geq a_{i,j}^2 \geq \cdots \geq a_{i,j}^{e_i}.\end{align*}$$
We define a module
$\omega _{\max ,i} = \bigoplus _{j} \omega _{\max , i, j}$
, where
$$\begin{align*}\omega_{\max,i,j} := k[\varepsilon_i]^{a_{i,j}^{e_i}} \bigoplus (\varepsilon_i)^{a_{i,j}^{e_{i-1}} - a_{i,j}^{e_i}} \bigoplus \cdots \bigoplus (\varepsilon_i^{e_i-1})^{a_{i,j}^1 - a_{i,j}^2}.\end{align*}$$
The maximal KR stratum
$\mathscr {A}_k^{w_0}$
can be described as follows:
$x \in \mathscr {A}_k^{w_0}(k) $
if and only if the following condition (dependent on the type of the index i) holds:
-
• Case (AL/AU): Under the natural decomposition
$\omega _{x,i} = \omega _{x,i,1} \bigoplus \omega _{x,i,2}$
given by the
$R_i / F_i$
-action, we require that
$\omega _{x,i,1} \simeq \omega _{\max ,i}$
. -
• Case (C): We require that
$\omega _{x,i} \simeq \omega _{\max , i} = k[{\varepsilon }_i]^{d_i} \subset k[{\varepsilon }_i]^{2 d_i}$
.
This condition comes from the explicit description of the maximal element in
$\operatorname {\mathrm {Adm}}(\mu _i)_{K_i}$
.
Let
$x\in \mathscr {A}_k^{w_0}(k)$
. In the case (C) we have
$a_{i,j}^l = d_{i,j}^{l}$
for all l, then
$\omega _{\max ,i,j}[\varepsilon _i^l]$
has rank
$d_{i,j}^1 + \cdots + d_{i,j}^l$
. This forces
$$\begin{align*}{\mathscr{F}}_{i,j}^l = \omega_{x,i,j}[\varepsilon^l_i].\end{align*}$$
Hence the splitting structure over
$\omega _{x,i,j}$
is unique. The case (AL/AU) is similar. Therefore the splitting structure over
$\omega _{x}$
is unique, and
$\pi : \pi ^{-1}(\mathscr {A}_k^{w_0}) \simeq \mathscr {A}_k^{w_0}$
is an isomorphism.
Since there is a unique maximal KR stratum in
${\mathscr {A}}_k$
, we have a unique maximal EKOR stratum in
${\mathscr {A}}_k$
. Recall that for each
$1\leq i\leq r$
, we have
${\mathcal {G}}_{i,0}^{\mathrm {spl}}\simeq {\mathcal {G}}^{\operatorname {\mathrm {rdt}},e_i}_{i,0}$
. We get a map
${\mathcal {G}}_0^{\mathrm {spl}}\rightarrow {\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
which is induced by the projection to the first factor
${\mathcal {G}}_{i,0}^{\mathrm {spl}}\rightarrow {\mathcal {G}}^{\operatorname {\mathrm {rdt}}}_{i,0}$
for each i. Let
$\mu '$
be the cocharacter of
${\mathcal {G}}^{\operatorname {\mathrm {rdt}}}_0$
induced by
$\mu $
under this map. As a continuation of Proposition 3.15, we have
Proposition 3.16. Let
$U_{\mathrm {KR}}=\mathscr {A}_k^{w_0}$
be the maximal KR stratum of
$\mathscr {A}_k$
. Then the morphism
$\zeta : {\mathscr {A}}_k^{\mathrm {spl}} \to {{\mathcal {G}}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_k$
induces a morphism
$$\begin{align*}\zeta_1: \pi^{-1}(U_{\mathrm{KR}}) \to {{\mathcal{G}}_0^{\operatorname{\mathrm{rdt}}}}\text{-}\mathrm{Zip}^{\mu'}_k.\end{align*}$$
Moreover, the natural morphism
$\pi : \mathscr {A}^{\mathrm {spl}}_k \to \mathscr {A}_k$
induces a commutative diagram
where
$\zeta _2=\zeta _{w_0}$
is the zip morphism on the maximal KR stratum of
${\mathscr {A}}_k$
constructed in subsection A.3.
Proof. The projection
${\mathcal {G}}_0^{\mathrm {spl}} \to {\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
induces a morphism
${{\mathcal {G}}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_k\rightarrow {{\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}}\text {-}\mathrm {Zip}^{\mu '}_k$
. Composing with
$\zeta : {\mathscr {A}}_k^{\mathrm {spl}} \to {{\mathcal {G}}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_k$
and restricting to
$\pi ^{-1}(U_{\mathrm {KR}})$
, we get a morphism
$$\begin{align*}\zeta_1: \pi^{-1}(U_{\mathrm{KR}}) \to {\mathcal{G}}_0^{\operatorname{\mathrm{rdt}}}\text{-}\mathrm{Zip}^{\mu'}_{k}.\end{align*}$$
By Proposition 3.15, the splitting structure over
$U_{\mathrm {KR}}$
is unique, hence the EO strata in
$\pi ^{-1}(U_{\mathrm {KR}})$
are uniquely determined by the fiber of
$\zeta _1$
. In other words, the restriction of the universal
${\mathcal {G}}_0^{\mathrm {spl}}$
-zip of type
$\mu $
to
$\pi ^{-1}(U_{\mathrm {KR}})$
is uniquely determined by the associated
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zip of type
$\mu '$
. To prove that the above diagram commutes, we need to show that this
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zip is the pullback (under
$\pi $
) of the
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zip on
$U_{\mathrm {KR}}$
given by
$\zeta _2=\zeta _{w_0}$
.
Let
$x = (A, \lambda , \iota , \alpha ) \in U_{\mathrm {KR}}(k)$
and
$y = \pi ^{-1}(x)$
. We will explicitly compare the
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zips at x and y. The argument will be dependent on the type of the indexes i. We first investigate the
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zip at x.
Case (AL/AU): Fix an isomorphism
$$\begin{align*}{\mathcal{H}}_{x,i} \simeq \Lambda_{k,i} = k[{\varepsilon}_i]^{\oplus2 d_i f_i}\end{align*}$$
and
$\Lambda _{k,i}$
decomposes as
$W \oplus W'$
, with
$W = k[{\varepsilon }_i]^{\oplus d_i f_i}$
,
$W'$
the dual of W. There are induced Frobenius morphism F and Verschiebung morphism V on
$\Lambda _{k,i}$
. The F-zip associated to x (with
${\mathcal {G}}_{i,0}^{\operatorname {\mathrm {rdt}}}$
-structure) induces an F-zip with
$\kappa _i$
-action
$M = (W, C, D, \iota )$
given by
$$\begin{align*}W = k[{\varepsilon}_i]^{\oplus d_i f_i},\quad C = \operatorname{\mathrm{Ker}}(V|_W),\quad D = \operatorname{\mathrm{Ker}}(F|_W),\end{align*}$$
and M determines the F-zip associated to x.
By the proof of Proposition 3.15, we have
$C = \bigoplus _j C_j$
, where
$$\begin{align*}C_j \simeq k[{\varepsilon}_i]^{\oplus a_{i,j}^{e_i}} \bigoplus (\varepsilon_i)^{\oplus(a_{i,j}^{e_{i-1}} - a_{i,j}^{e_i})} \bigoplus \cdots \bigoplus ({\varepsilon}_i^{e_i-1})^{\oplus (a_{i,j}^1 - a_{i,j}^2)}.\end{align*}$$
The EO strata inside
$U_{\mathrm {KR}}$
are determined by an F-zip
$(M', C', D', \iota ')$
with
${\mathcal {G}}_{i,0}^{\mathrm {rdt}}$
-structure (recall that
${\mathcal {G}}_{i,0} = \operatorname {\mathrm {Res}}_{\kappa _i[{\varepsilon }_i] | \mathbb {F}_p} H_i, {\mathcal {G}}_{i,0}^{\mathrm {rdt}} = \operatorname {\mathrm {Res}}_{\kappa _i |\mathbb {F}_p} H_i$
). More precisely, we have
-
•
$M' = M / {\varepsilon }_i M = k^{\oplus d_i}.$
-
•
$C'$
is the natural image of C in
$M'$
, we have
$C' = \bigoplus _j C^{\prime }_j$
and
$\dim _k C^{\prime }_j = a_{i,j}^{e_i}$
. -
• Under the natural isomorphism
${\varepsilon }_i^{e_i-1}M \simeq M'$
, let
$D' := D \cap {\varepsilon }_i^{e_i-1}M$
, we have
$D' = \bigoplus _j D^{\prime }_j$
and
$\dim _k D^{\prime }_j = d_i - a_{i,j}^{e_i}$
. -
• The morphisms
$F,V$
of M restrict to the morphisms
$$\begin{align*}F: M' \to {\varepsilon}_i^{-1}({\varepsilon}_i C) / ({\varepsilon}_i C) \quad \textrm{and}\quad V: {\varepsilon}_i^{-1}({\varepsilon}_i C) / ({\varepsilon}_i C) \to M'.\end{align*}$$
Composing with the natural isomorphism (same as Lemma 3.6)
give semilinear isomorphisms
$$\begin{align*}{\varepsilon}_i^{-1}({\varepsilon}_i C) / ({\varepsilon}_i C) \simeq M'\end{align*}$$
$F', V'$
of
$M'$
, such that
$$\begin{align*}\operatorname{\mathrm{Ker}}(F') = \operatorname{\mathrm{Im}}(V') = D', \quad \operatorname{\mathrm{Ker}}(V') = \operatorname{\mathrm{Im}}(F') = C'.\end{align*}$$
The morphism
$\iota ' = (\iota ^{\prime }_0, \iota ^{\prime }_1)$
is induced from
$F', V'$
.
The type of a
${\mathcal {G}}_{i,0}^{\mathrm {rdt}}$
-zip is determined by a cocharacter
$\mu '$
associated to the tuple
$(a_{i,j}^{e_i})_j$
(up to conjugate).
Case (C): Fix an isomorphism
$$\begin{align*}{\mathcal{H}}_{x,i} \simeq \Lambda_{k,i} = k[{\varepsilon}_i]^{\oplus 2 d_i f_i}.\end{align*}$$
The F-zip associated to x (with
${\mathcal {G}}_{i,0}^{\operatorname {\mathrm {rdt}}}$
-structure) induces an F-zip
$M = (\Lambda _{k,i}, C, D, \iota )$
,
$C = \operatorname {\mathrm {Ker}}(V), D = \operatorname {\mathrm {Ker}}(F)$
. In this case, we have
$d_{i,j}^l = d_i$
, and
$C = \bigoplus _j C_j$
, where
$$\begin{align*}C_j \simeq k[{\varepsilon}_i]^{\oplus d_i} \subset k[{\varepsilon}_i]^{\oplus 2 d_i}.\end{align*}$$
Similar to the case (AL/AU), such data induce an F-zip
$(M', C', D', \iota ')$
with
${\mathcal {G}}_{i,0}^{\mathrm {rdt}}$
-structure, with type
$(1^g, 0^g)^{e_i f_i}$
.
On the other hand, fixing an isomorphism
${\mathcal {M}}_y \simeq \Lambda ^{\mathrm {spl}}_k$
with associated F-zip
$(\Lambda _k^{\mathrm {spl}}, C, D, \iota )$
, we have
$$\begin{align*}{\mathcal{M}}_{i}^{e_i} = {\varepsilon}_i^{-1}({\varepsilon}_i C) / {\varepsilon}_i C, \quad {\mathcal{M}}_{i}^1 = {\varepsilon}_i^{e_i-1} \Lambda_{k,i}.\end{align*}$$
By identifying
${\mathcal {M}}_{i}^{e_i}$
and
${\mathcal {M}}_{i}^1$
, our construction in subsection 3.2 induces the same F-zip with
${\mathcal {G}}_{i,0}^{\mathrm {rdt}}$
-structure
$(M', C', D', \iota ')$
as that at x. This finishes the proof.
Corollary 3.17. The
$\mu $
-ordinary locus of
$\mathscr {A}_k^{\mathrm {spl}}$
coincides with the maximal EO stratum, thus it is open dense in
${\mathscr {A}}_k^{\mathrm {spl}}$
.
Proof. Note that the Weil restriction of a quasi-split group remains quasi-split, so the group
$G_{\mathbb {Q}_p}$
is quasi-split. Let
$U_{\mathrm {EKOR}}$
be the maximal EKOR stratum of
$\mathscr {A}_k$
. Then
$U_{\mathrm {EKOR}}\subset U_{\mathrm {KR}}$
. The main result of [Reference He and Nie24] shows that the
$\mu $
-ordinary locus of
$\mathscr {A}_k$
is the same as
$U_{\mathrm {EKOR}}$
. By the above proposition, we have
$$\begin{align*}\pi^{-1}(U_{\mathrm{EKOR}}) = U,\end{align*}$$
hence the maximal EO stratum U coincides with the
$\mu $
-ordinary locus of
$\mathscr {A}^{\mathrm {spl}}_k$
.
The open density of the
$\mu $
-ordinary locus was proved in [Reference Bijakowski and Hernandez6, Theorem 1.2] by a different method.
3.6 Hodge strata and pullbacks of Kottwitz-Rapoport strata
In [Reference Bijakowski and Hernandez6], Bijakowski-Hernandez introduced a Hodge stratification. Here, we provide an interpretation of their Hodge stratification in our language.
Recall the local setup of [Reference Bijakowski and Hernandez5, Reference Bijakowski and Hernandez6]. Let L be a finite extension of
${\mathbb {Q}}_p$
of degree
$n = e f$
, where e is the ramification index, and f the residue degree of
$L|{\mathbb {Q}}_p$
. Let
$\pi $
be a uniformizer of
${\mathcal {O}}_L$
. Let
$\mathbf {G}$
be a p-divisible group over k with
${\mathcal {O}}_L$
action
$\iota $
, such that its height is
$nh$
. This is the local geometric datum in the case of type (AL). In the case of type (C) or (AU), we require moreover that there to be a polarization
$\lambda : \mathbf {G}\rightarrow \mathbf {G}^\vee $
of
$\mathbf {G}$
. Note that even in the type (AL) case, we have a natural polarization
$\lambda : \mathbf {G}\times \mathbf {G}^\vee \rightarrow \mathbf {G}^\vee \times \mathbf {G}$
. Let
$(M,F)$
be the contravariant F-crystal associated to the p-divisible group
$\mathbf {G}$
. Then M is a finite free
$W(k)$
-module of rank
$nh$
and
$F: M \to M$
a
$\sigma $
-linear injective morphism. The
${\mathcal {O}}_L$
-action induces a decomposition of the
$W(k)$
-module
$$\begin{align*}M = \bigoplus_{\tau \in J} M_{\tau},\end{align*}$$
where
$J := \operatorname {\mathrm {Hom}}({\mathcal {O}}_{L^{\operatorname {\mathrm {ur}}}}, W(k))$
, and
$M_\tau $
is the
$W(k)$
-submodule of M such that
${\mathcal {O}}_L$
-acts through
$\tau : {\mathcal {O}}_{L^{\operatorname {\mathrm {ur}}}} \to W(k)$
. In the case of type (C) or (AU), there is an induced perfect pairing
$M\times M\rightarrow W(k)$
from
$\lambda $
, which is compatible with the decomposition. As F is
$\sigma $
-linear, we have
$$\begin{align*}F(M_{\sigma^{-1}\tau}) \subset M_\tau.\end{align*}$$
For each
$\tau \in J$
, there is an isomorphism
$$\begin{align*}M_\tau / F(M_{\sigma^{-1}\tau}) \simeq \bigoplus_{1 \leq i \leq h} W(k)/a_{\tau,i} W(k),\end{align*}$$
where each
$a_{\tau ,i} \in W(k)-\{0\}$
and we assume that
$$\begin{align*}v(a_{\tau,1}) \geq v(a_{\tau,2}) \geq \dots \geq v({a_{\tau,h}}).\end{align*}$$
For each
$0 \leq i \leq h$
, the i-th coordinate of the Hodge polygon is:
$$\begin{align*}\operatorname{\mathrm{Hdg}}_{{\mathcal{O}}_L, \tau}(M,F)(i) := v(a_{\tau,1}) + \cdots + v(a_{\tau,h-i+1}).\end{align*}$$
Note that our polygon is upper convex, whereas [Reference Bijakowski and Hernandez5] uses lower convex polygon. All statements of loc. cit. about polygons still hold, after replacing minimal by maximal. The Hodge polygon of
$\underline {\mathbf {G}}=(\mathbf {G},\iota ,\lambda )$
is defined as a polygon starting at
$(0,0)$
and ending at
$(h,d)$
such that for
$0 \leq i \leq h$
$$\begin{align*}\operatorname{\mathrm{Hdg}}(\underline{\mathbf{G}})(i) = \frac{1}{f} \sum_{\tau \in J} \operatorname{\mathrm{Hdg}}_{{\mathcal{O}}_L, \tau}(M,F)(i),\end{align*}$$
where
$d=\frac {1}{f}\sum _{\tau \in J}d_\tau $
and
$d_\tau =\sum _{i=1}^h v(a_{\tau ,i})$
. The precise form of the pair of numbers
$(h,d)$
depends on the type (C), (AL) or (AU) which is being studied. Note that since we have an isomorphism
$$\begin{align*}\omega_{\mathbf{G}}\simeq M/FM\end{align*}$$
as
${\mathcal {O}}_L$
-modules, the Hodge polygon of
$\underline {\mathbf {G}}$
depends only on the
${\mathcal {O}}_L$
-module
$\omega _{\mathbf {G}}$
.
Now fix integers
$0 \leq d_{\tau }^l \leq h$
for
$\tau \in J, 1 \leq l \leq e$
, we say that
$(M,F)$
satisfies the Pappas-Rapoport condition with respect to
$\mu := (d_{\tau }^l)$
, if for every
$\tau $
, there exists a filtration
$$\begin{align*}F_\tau M_{\sigma^{-1}(\tau)} = \operatorname{\mathrm{Fil}}^0 M_\tau \subset \operatorname{\mathrm{Fil}}^1 M_\tau \subset \cdots \subset \operatorname{\mathrm{Fil}}^{e} M_\tau = M_\tau, \end{align*}$$
such that
-
• For each
$0 \leq l \leq e$
,
$\operatorname {\mathrm {Fil}}^l M_\tau $
is a sub
$W(k)$
-module of
$M_\tau $
, -
• One has
$\pi \cdot \operatorname {\mathrm {Fil}}^{l} M_\tau \subset \operatorname {\mathrm {Fil}}^{l-1} M_\tau $
for all
$1 \leq l \leq e$
, -
•
$\operatorname {\mathrm {Fil}}^l M_\tau / \operatorname {\mathrm {Fil}}^{l-1} M_\tau $
is a k-vector space of dimension
$d_{\tau }^l$
for all
$1 \leq l \leq e$
.
Given the Pappas-Rapoport condition with respect to
$\mu $
, the maximal possible Hodge polygon is given by the polygon
$\operatorname {\mathrm {PR}}(\mu )$
, where for each
$\tau $
, let
$$\begin{align*}\operatorname{\mathrm{PR}}_\tau(\mu)(s) := \frac{1}{e} \sum_{l=1}^e \max(s-h+d_{\tau}^l),\end{align*}$$
and
$\operatorname {\mathrm {PR}}(\mu )$
is the average of
$\operatorname {\mathrm {PR}}_\tau (\mu )$
for
$\tau \in J$
. Recall the following result
Theorem 3.18 [Reference Bijakowski and Hernandez5].
Let
$\underline {\mathbf {G}} = (\mathbf {G}, \iota , \lambda ,\operatorname {\mathrm {Fil}}^{\bullet })$
be a p-divisible group over a perfect field k of characteristic p, with an
${\mathcal {O}}_L$
-action, plus a Pappas-Rapoport condition given by
$\mu = (d_\tau ^l)_{\tau ,l}$
. We have three polygons associated to
$\underline {\mathbf {G}}$
, the Newton polygon (upper convex)
$\operatorname {\mathrm {Newt}}(\underline {\mathbf {G}})$
and the Hodge polygon
$\operatorname {\mathrm {Hdg}}(\underline {\mathbf {G}})$
with respect to
$\underline {\mathbf {G}}$
, and a PR polygon
$\operatorname {\mathrm {PR}}(\mu )$
determined by the Pappas-Rapoport condition with respect to
$\mu $
. One has the following inequalities:
$$\begin{align*}\operatorname{\mathrm{Newt}}(\underline{\mathbf{G}}) \leq \operatorname{\mathrm{Hdg}}(\underline{\mathbf{G}}) \leq \operatorname{\mathrm{PR}}(\mu).\end{align*}$$
Using our language, let
$x \in {\mathscr {A}}^{\mathrm {spl}}(k)$
, and
$\mathbf {G}_x$
the p-divisible group associated to x. Then
$\mathbf {G}_x$
decomposes as direct sum
$\mathbf {G}_x=\bigoplus _{i=1}^r\mathbf {G}_{x,i}$
, and each
$\mathbf {G}_{x,i}$
is a p-divisible group over k with
${\mathcal {O}}_{F_i}$
-action and polarization
$\lambda $
, plus a PR condition with respect to
$\mu _{i}$
. So for each i, there are three polygons
$\operatorname {\mathrm {Newt}}_i(x):=\operatorname {\mathrm {Newt}}(\mathbf {G}_{x,i}), \operatorname {\mathrm {Hdg}}_i(x):=\operatorname {\mathrm {Hdg}}(\mathbf {G}_{x,i}), \operatorname {\mathrm {PR}}(\mu _i)$
associated to x. Note that for each i, we have an isomorphism of
${\mathcal {O}}_{F_i}$
-module
$\omega _{x,i}\simeq \omega _{\mathbf {G}_{x,i}}$
.
Corollary 3.19. Let
$U_{\mathrm {KR}}$
be the maximal open dense KR stratum of
${\mathscr {A}}_k$
and
$\pi : {\mathscr {A}}_k^{\mathrm {spl}} \to {\mathscr {A}}_k$
the forgetful morphism. For each
$x\in {\mathscr {A}}_k^{\mathrm {spl}}$
, we have
$\operatorname {\mathrm {Hdg}}_i(x) = \operatorname {\mathrm {PR}}(\mu _i)$
for all i if and only if
$x \in \pi ^{-1}(U_{\mathrm {KR}})$
.
Proof. This follows from the description of the maximal KR stratum in the proof of Proposition 3.15.
Note that
$\pi ^{-1}(U_{\mathrm {KR}})$
is the generalized Rapoport locus in [Reference Bijakowski and Hernandez6], where it is defined as the maximal Hodge stratum of
${\mathscr {A}}_k^{\mathrm {spl}}$
. Also note in general the closure relation does not hold for the Hodge stratification, as claimed by [Reference Bijakowski and Hernandez6].
We give a group-theoretic reformulation of Hodge polygon. For simplicity, we assume
$r=1$
(the general case follows by combining the independent data for all
$i\in I$
) in our previous notations. Let
$F_1$
be a finite extension over
${\mathbb {Q}}_p$
of degree
$n_1 = e_1 f_1$
, with
$e_1$
its ramification index and
$f_1$
its residue degree. We also fix an unramified group H over
$F_1$
and let
$G_1= \operatorname {\mathrm {Res}}_{F_1 | {\mathbb {Q}}_p} H$
. The maximal parahoric subgroup of
$G_1(\mathbb {Q}_p)$
is
$K = H({\mathcal {O}}_{F_1})$
, where we use the same H as the reductive model of H. Let
$\breve {{\mathbb {Q}}}_p$
be the completion of maximal unramified extension of
${{\mathbb {Q}}}_p$
. For simplicity, we will write
$\breve {G}_1 = G_1(\breve {{\mathbb {Q}}}_p)$
and similar symbols for other groups.
Choose a maximal torus
$T \subset G_1$
and N its normalizer. Let
$\breve {I}$
be the Iwahori subgroup of
$\breve {G}_1$
. The Iwahori-Weyl group is
$$\begin{align*}\widetilde{W} = N(\breve{{\mathbb{Q}}}_p) / (T(\breve{{\mathbb{Q}}}_p) \cap \breve{I}). \end{align*}$$
We have the following isomorphism
$$\begin{align*}\widetilde{W} \simeq X_*(T)_{\Gamma_0} \rtimes W_0,\end{align*}$$
where
$\Gamma _0 = \operatorname {\mathrm {Gal}}(\overline {{\mathbb {Q}}}_p / \breve {{\mathbb {Q}}}_p)$
and
$W_0$
is the relative Weyl group of
$G_{\breve {{\mathbb {Q}}}_p}$
. Let
$\breve {K}\subset \breve {G}_1$
be the induced parahoric subgroup and
$$\begin{align*}W_K = (N(\breve{{\mathbb{Q}}}_p) \cap \breve{K}) / (T(\breve{{\mathbb{Q}}}_p) \cap \breve{I}) \subset \widetilde{W},\end{align*}$$
then
$W_K \simeq W_0$
is the section of
$W_0$
in
$\widetilde {W}$
, since K is a special parahoric subgroup. The following natural bijection
$$\begin{align*}W_K \backslash \widetilde{W} / W_K \simeq X_*(T)_{\Gamma_0} / W_0 \end{align*}$$
gives the natural injective map
$$\begin{align*}h: W_K \backslash \widetilde{W} / W_K \to X_*(T)_{\Gamma_0, {\mathbb{Q}}}^{+}.\end{align*}$$
Since
$G_1$
is a Weil restriction of
$H / F_1$
, this implies
$$\begin{align*}\breve{G}_1= H(F_1 \otimes_{{\mathbb{Q}}_p} \breve{{\mathbb{Q}}}_p) = \prod_{\tau: F_1^{\operatorname{\mathrm{ur}}} \to \breve{{\mathbb{Q}}}_p} H(\breve{F}_1).\end{align*}$$
For simplicity, we just write
$\breve {G}_1= \breve {H}^{f_1}$
, where
$\breve {H} = H(\breve {F}_1)$
. Similarly we have
$T_{\breve {{\mathbb {Q}}}_p} \simeq T_1^f$
with
$T_1\subset H$
a maximal torus, which induces natural maps
$$\begin{align*}X_*(T)_{\Gamma_0,\mathbb{Q}} \simeq (X_*(T_1)_{\Gamma_0,\mathbb{Q}})^f \to X_*(T_1)_{\Gamma_0,{\mathbb{Q}}}.\end{align*}$$
The last map sends
$(\chi _1, \dots , \chi _f)$
to
$\frac {1}{f} (\chi _1 + \cdots + \chi _f)$
. Composing this map with h gives us a map
$$\begin{align*}\operatorname{\mathrm{Hdg}}: W_K \backslash \widetilde{W} / W_K \to X_*(T_1)_{\Gamma_0, {\mathbb{Q}}}^+.\end{align*}$$
Recall the
$\mu $
-admissible set
$\operatorname {\mathrm {Adm}}(\mu )_K \subset W_K \backslash \widetilde {W} / W_K$
. Restricting
$\operatorname {\mathrm {Hdg}}$
to it gives the following proposition.
Proposition 3.20. For
$x\in {\mathscr {A}}^{\mathrm {spl}}(k)$
, let
$w \in \operatorname {\mathrm {Adm}}(\mu )_K$
be the KR type of
$\pi (x)\in {\mathscr {A}}(k)$
. Then the Hodge polygon of x is given by
$\operatorname {\mathrm {Hdg}}(w) \in X_*(T_1)_{\Gamma _0, {\mathbb {Q}}}^+$
.
Proof. Let
$(M,F)$
be the F-crystal with additional structure attached to x, which depends only on
$\pi (x)$
. The isomorphism class of
$M/FM$
as
${\mathcal {O}}_L \otimes W(k)$
-module is given by an element in
$\operatorname {\mathrm {Adm}}(\mu )_K$
, consisting of a tuple in
$X_*(T)_{\Gamma _0}$
. The average of the tuple in
$X_*(T)_{\Gamma _0}$
gives the Hodge polygon of the F-crystal
$(M,F)$
, which is (as usual) viewed as an element of
$X_*(T_1)_{\Gamma _0, {\mathbb {Q}}}^+$
.
Corollary 3.21. The Hodge stratification of
${\mathscr {A}}_k^{\mathrm {spl}}$
descends to
${\mathscr {A}}_k$
under the map
$\pi : {\mathscr {A}}_k^{\mathrm {spl}}\rightarrow {\mathscr {A}}_k$
. In particular, each Hodge stratum of
${\mathscr {A}}_k^{\mathrm {spl}}$
is a finite disjoint union of preimages of Kottwitz-Rapoport strata of
${\mathscr {A}}_k$
under the natural map
$\pi : {\mathscr {A}}_k^{\mathrm {spl}}\rightarrow {\mathscr {A}}_k$
.
Recall that Corollary 3.19 states that the maximal Hodge stratum is exactly the preimage of the maximal Kottwitz-Rapoport stratum. One checks easily that
$\operatorname {\mathrm {Hdg}}(w_0)=\operatorname {\mathrm {PR}}(\mu )$
.
4 Hasse invariants for EO strata
In this section, we apply the general theory of group-theoretical Hasse invariants of [Reference Goldring and Koskivirta19, Reference Goldring and Koskivirta20] to the smooth scheme
${\mathscr {A}}_{0}^{\mathrm {spl}}$
, by the map
$\zeta : {\mathscr {A}}_{0}^{\mathrm {spl}}\rightarrow {\mathcal {G}_0^{\mathrm {spl}}}\text {-}\mathrm {Zip}^{\mu }_\kappa $
constructed in the last section. We will discuss some examples.
4.1 Group-theoretical Hasse invariants
We come back to the setting of subsection 3.1. Let
$(G,\mu )$
be a cocharacter datum over
$\mathbb {F}_p$
, this means that G is a connected reductive group over
$\mathbb {F}_p$
and
$\mu $
is a cocharacter of G defined over a finite field
$\kappa $
over
$\mathbb {F}_p$
. Recall that
$(P_+,P_-)$
is the pair of opposite parabolic subgroups of
$G_\kappa $
determined by
$\mu $
, and
$L := P_- \cap P_+$
the Levi subgroup of
$G_\kappa $
. Let
$U_+$
(resp.
$U_-$
) the unipotent radical of
$P_+$
(resp.
$P_-$
). The zip group
$E_{G,\mu }$
is the subgroup of
$G_\kappa \times G_\kappa $
$$\begin{align*}E_{G,\mu}= \{ (p_+ = l u_+, p_- = l^{(p)} u_-) \in P_+ \times P_-^{(p)} \mid l \in L, u_+ \in U_+, u_- \in U_-^{(p)} \}. \end{align*}$$
It acts on
$G_\kappa $
as
$(p_+, p_-) \cdot g := p_+ g p_-^{-1}$
. By Theorem 3.4, there is a canonical isomorphism of stacks
$$\begin{align*}{G}\text{-}\mathrm{Zip}^{\mu}_\kappa \cong [E_{G,\mu}\backslash G_\kappa].\end{align*}$$
Let
$k=\overline {\kappa }$
and
${G}\text {-}\mathrm {Zip}^{\mu } ={G}\text {-}\mathrm {Zip}^{\mu }_k=[E_{G,\mu ,k} \backslash G_k]$
. Given
$\lambda \in X^*(L)$
, which can be viewed as an element of
$X^*(E_{G,\mu })$
through the projection
$E_{G,\mu }\to L$
, one can associate a line bundle
${\mathcal {V}}(\lambda )$
over
$[E_{G,\mu ,k} \backslash G_k]$
such that
$$\begin{align*}H^0([E_{G,\mu,k} \backslash G_k], {\mathcal{V}}(\lambda)) = \{f: G_k \to {\mathbb{A}}^1_k \mid f(gx) = \lambda(g)f(x) \text{ for all } g \in E_{G,\mu,k} , x \in G_k\}.\end{align*}$$
Let S be a scheme or an algebraic stack over k with a morphism
$\zeta : S \rightarrow {G}\text {-}\mathrm {Zip}^{\mu }$
.
Definition 4.1. For every
$w \in {}^J W$
, denote by
$S_w$
the EO stratum of S associated to w, i.e.,
$S_w = \zeta ^{-1}(w)$
and
$\overline {S}_w$
its Zariski closure in S. A Hasse invariant for
$(\lambda , S_w)$
is a section
$h_w \in H^0(\overline {S}_w, \mathcal {V}(n \lambda ))$
for some positive integer n, such that its nonvanishing locus
$D(h_w)$
is
$S_w$
. If such
$h_w$
exists for all w, then
$\lambda $
is called a Hasse generator for S.
The following proposition shows that the Hasse generator is unique up to
$k^\times $
if it exists.
Proposition 4.2 [Reference Goldring and Koskivirta19].
Let
$\lambda \in X^*(L)$
and
$U_\mu $
the unique open dense E-orbit in
$G_k$
, then
-
(1) One has
$\dim _k(H^0({G}\text {-}\mathrm {Zip}^{\mu }, \mathcal {V}(\lambda ))) \leq \dim _k(H^0(U_\mu , \mathcal {V}(\lambda ))) \leq 1$
. -
(2) There is a positive integer
$N_\mu $
such that the space
$H^0(U_\mu , \mathcal {V}(N_\mu \lambda ))$
has dimension one.
Recall that a cocharacter datum
$(G,\mu )$
is Hodge type if there is a symplectic embedding
$G\hookrightarrow \operatorname {\mathrm {GSp}}_{2g}$
over
$\mathbb {F}_p$
such that
$\mu $
induces the standard minuscule cocharacter of
$\operatorname {\mathrm {GSp}}_{2g}$
. For such datum, there is a Hodge line bundle
${\mathcal {V}}(\eta _\omega )$
over
$[E_{G,\mu } \backslash G_\kappa ]$
by pull-back from the given symplectic embedding of G (in general
${\mathcal {V}}(\eta _\omega )$
depends on the symplectic embedding). We have the following theorem.
Theorem 4.3 [Reference Goldring and Koskivirta19].
Let
$(G,\mu )$
be a cocharacter datum over
$\mathbb {F}_p$
and assume that
$\mu $
is minuscule. For
$p>2$
, the stack
${G}\text {-}\mathrm {Zip}^{\mu }$
admits a Hasse generator.
Moreover, if
$(G,\mu )$
is Hodge type (
$p=2$
allowed), then the Hodge line bundle is associated to a Hasse generator.
4.2 Length Hasse invariants
Keep notations as above. Let
$d=\langle 2\rho ,\mu \rangle $
, where
$\rho $
is the half sum of positive (absolute) roots of G. Recall the subsets
$G_w\subset G_k$
as in Theorem 3.5 attached to
$w\in {}^JW$
. For any integer
$0 \leq j \leq d$
, define
$$\begin{align*}G_j = \bigcup_{\ell(w)=j} G_w\end{align*}$$
with the reduced subscheme structure. It is called the j-th length stratum of
$G_k$
. By [Reference Goldring and Koskivirta20], we have the following identities:
$$\begin{align*}\overline{G}_j = \bigcup_{\ell(w)=j} \overline{G}_w = \bigcup_{\ell(w)\leq j} G_w.\end{align*}$$
In the rest of this section, assume that
$(G,\mu )$
is of Hodge type.
Proposition 4.4 ([Reference Goldring and Koskivirta20, Proposition 5.2.2]).
There exists an integer
$N' \geq 1$
such that for each
$0 \leq j \leq d$
, a section
$h_j \in H^0([E_{G,\mu ,k} \backslash \overline {G}_j], {\mathcal {V}}(\eta _\omega )^{N'})$
such that
$D(h_j) = [E_{G,\mu ,k} \backslash G_j]$
.
Such
$h_j$
will be called a length Hasse invariant.
Now we assume that S is a k-scheme and
$\zeta : S \rightarrow {G}\text {-}\mathrm {Zip}^{\mu }$
is a morphism of stacks (maybe not smooth). For a character
$\lambda \in X^{\ast } (L)$
, write
$\mathcal {V}_S (\lambda ) =\zeta ^{\ast } (\mathcal {V} (\lambda ))$
. For
$w \in {}^J W$
and
$j \in \{ 0,\ldots , d \}$
, we define the locally closed subsets of S:
$S_w, S_w^{\ast }, S_j, S_j^{\ast }$
as preimage of
$[E_{G,\mu ,k} \backslash G_w], [E_{G,\mu ,k} \backslash \overline {G}_w], [E_{G,\mu ,k} \backslash G_j], [E_{G,\mu ,k} \backslash \overline {G}_j]$
, respectively, equipped with reduced subscheme structure from S.
Proposition 4.5 ([Reference Goldring and Koskivirta20, Proposition 5.2.3]).
Assume that
-
(1) The scheme S is equi-dimensional of dimension d.
-
(2) The stratum
$S_w$
is non-empty for all
$w \in {}^J W$
. -
(3) The stratum
$S_e = S_0$
is zero-dimensional.
Then we have:
-
(1) The schemes
$S_j$
and
$S_j^{\ast }$
are equi-dimensional of dimension j. -
(2) The sections
$h_j$
are injective; equivalently
$S_j$
is open dense in
$S_j^{\ast }$
. -
(3) For
$w \in {}^J W$
,
$S_w$
is equi-dimensional of dimension
$\ell (w)$
.
4.3 Hasse invariants on splitting models
Back to splitting models, let
$S = {\mathscr {A}}^{\mathrm {spl}}_k$
. Recall that by Theorem 3.13, there is a smooth surjective morphism
$$\begin{align*}\zeta: S \to {{\mathcal{G}}_0^{\mathrm{spl}}}\text{-}\mathrm{Zip}^{\mu}_k.\end{align*}$$
For each
$w \in {}^J W$
, let
$S_w = \zeta ^{-1}(w)$
be the EO stratum of S. By our construction,
${\mathcal {G}}_0^{\mathrm {spl}}$
is the similitude group of the lattice
$\Lambda ^{\mathrm {spl}}_0$
with a pairing induced from that on
$\Lambda $
, hence the pair
$({\mathcal {G}}_0^{\mathrm {spl}},\mu )$
is of Hodge type and the general theory of Hasse invariants applies. For simplicity, here in the following we denote
$\mathsf {E}=E_{{\mathcal {G}}_0^{\mathrm {spl}},\mu ,k}$
.
Corollary 4.6. There exists an integer
$N \geq 1$
such that for every
$w \in {}^J W$
, there exists a section
$h_w \in H^0([\mathsf {E} \backslash \overline {{\mathcal {G}}_{0,w}^{\mathrm {spl}}}], {\mathcal {V}}(N \eta _\omega ))$
whose non-vanishing locus is precisely
$[\mathsf {E} \backslash {\mathcal {G}}_{0,w}^{\mathrm {spl}}]$
.
Corollary 4.7. Fix a large enough integer N as in the above corollary. For every EO stratum
$S_w \subset S$
, the section
$\zeta ^*(h_w) \in H^0(\overline {S}_w, \omega _{\operatorname {\mathrm {Hdg}}}^N)$
is
$G({\mathbb {A}}_f^p)$
-equivariant, and its non-vanishing locus is
$D(\zeta ^* (h_w)) = S_w$
.
Here we denote
$\omega _{\operatorname {\mathrm {Hdg}}}$
as the Hodge line bundle with weight
$\eta _\omega $
on
$S={\mathscr {A}}^{\mathrm {spl}}_k$
. We will use the same symbols
$h_w$
as their pullbacks to
$\overline {S}_w$
and call them the Hasse invariants of S. We also have the length Hasse invariants on S, and by our previous results in section 3, Proposition 4.5 holds for S.
4.4 Example: Hilbert modular varieties
Now consider the splitting models of Hilbert modular varieties. We would like to compare our construction with that of Reduzzi-Xiao in [Reference Reduzzi and Xiao56].
Let
$L|\mathbb {Q}$
be a totally real field extension and
$G = (\operatorname {\mathrm {Res}}_{L|\mathbb {Q}}\operatorname {\mathrm {GL}}_2)^{\det \in \mathbb {Q}^\times }$
the similitude group associated to the Hilbert moduli space with respect to L. Fix a prime number p and a prime to p level structure
$K^p \subset G({\mathbb {A}}_f^p)$
, which is defined in [Reference Reduzzi and Xiao56] as
$\Gamma _{00}(\mathcal {N})$
-level structures. Let F be a Galois extension of
${\mathbb {Q}}_p$
containing all the p-adic factors of L. Then we have a splitting model
${\mathscr {A}}^{\mathrm {spl}}$
defined over
${\mathcal {O}}_F$
with level
$K^p$
. Let k be an algebraic closure of the residue field of
${\mathcal {O}}_F$
, and
${\mathscr {A}}_0^{\mathrm {spl}} = {\mathscr {A}}^{\mathrm {spl}} \otimes k$
.
For any k-scheme S,
${\mathscr {A}}_0^{\mathrm {spl}}(S)$
classifies the isomorphism class of tuples
$(A, \lambda , \alpha , \underline {{\mathscr {F}}}_{\bullet })$
, where
-
(1)
$(A, \lambda )$
is a polarized abelian scheme over S with
${\mathcal {O}}_L$
-action, with level structure
$\alpha $
. -
(2)
$\underline {{\mathscr {F}}_{\bullet }} = ({\mathscr {F}}_{i,j}^l)_{1 \leq i \leq r, 1 \leq j \leq f_i, 0 \leq l \leq e_i}$
, each
${\mathscr {F}}_{i,j}^l$
is a locally free sheaf over S such that-
•
$0 = {\mathscr {F}}_{i,j}^0 \subset {\mathscr {F}}_{i,j}^1 \subset \cdots \subset {\mathscr {F}}_{i,j}^{e_i} = \omega _{A/S,i,j}$
and each
${\mathscr {F}}_{i,j}^l$
is stable under the
${\mathcal {O}}_L$
-action. -
• each subquotient
${\mathscr {F}}_{i,j}^l / {\mathscr {F}}_{i,j}^{l-1}$
is a locally free
${\mathcal {O}}_S$
-module of rank one. -
• the
${\mathcal {O}}_F$
-action on each subquotient
${\mathscr {F}}_{i,j}^l / {\mathscr {F}}_{i,j}^{l-1}$
factors through
$\sigma _{i,j}^l: {\mathcal {O}}_L \to {\mathcal {O}}_F$
.
-
Consider
$S = {\mathscr {A}}_0^{\mathrm {spl}}$
and
$(A,\lambda ,\alpha , \underline {{\mathscr {F}}_{\bullet }})$
the universal object over S. The sheaf
${\mathcal {H}}_{i,j}=H_{\operatorname {\mathrm {dR}}}^1(A/S)_{i,j}$
is a locally free
${\mathcal {O}}_S[\varepsilon _i]$
-module (
$\varepsilon _i^{e_i}=0$
) of rank two, where the
$\pi _i$
-action is given by
$\varepsilon _i$
. For each
$i, j$
denote
$\omega _{i,j}=\omega _{A/S,i,j}$
.
For each
$i,j,l$
, let
$h_{i,j}^l$
be the partial Hasse invariant defined by [Reference Reduzzi and Xiao56], which is a section of a certain line bundle over S. For a point
$x = (\underline {A}, \underline {{\mathscr {F}}_{\bullet }}) \in S(k)$
, the construction of partial Hasse invariants shows that
-
• For
$2 \leq l \leq e_i$
,
$h_{i,j}^l(x) = 0$
if and only if
$\varepsilon _i {\mathscr {F}}_{i,j}^l = {\mathscr {F}}_{i,j}^{l-2}$
. -
• For
$l = 1$
,
$h_{i,j}^1(x) = 0$
if and only if
${\mathscr {F}}_{i,j}^1 = \operatorname {\mathrm {Ker}}(\operatorname {\mathrm {Ver}}_{i,j}^1)$
.
The vanishing loci of these
$h_{i,j}^l$
cut out the stratification in [Reference Reduzzi and Xiao56]. We claim that their stratification coincides with the Ekedahl-Oort stratification defined in this paper.
For each
$i,j,l$
we have a locally free sheaf
${\mathcal {M}}_{i,j}^l = \varepsilon _i^{-1} {\mathscr {F}}_{i,j}^{l-1} /{\mathscr {F}}_{i,j}^{l-1} $
. Let
${\mathcal {M}}_i=\bigoplus _{j,l}{\mathcal {M}}_{i,j}^l $
. By our construction in subsection 3.2, there is a natural
$G_i:= \operatorname {\mathrm {Res}}_{\kappa _i|{\mathbb {F}}_{p}} \operatorname {\mathrm {GL}}_2^{e_i}$
-zip
$$\begin{align*}({\mathcal{M}}_{i}, C_{i}, D_{i}, \varphi_0, \varphi_1)\end{align*}$$
of type
$\mu _i = (1,0)^{e_if_i}$
over S. The maps
$V_{i,j}^l: {\mathcal {M}}_{i,j}^l \to {\mathcal {M}}_{i,j}^{l-1}$
(for
$l\geq 2$
) and
$V_{i,j}^1:{\mathcal {M}}_{i,j}^1 \to {\mathcal {M}}_{i,j-1}^{e_i,(p)}$
(for
$l=1$
) induce maps
$$\begin{align*}V_{i,j}^l: \omega_{i,j}^l \to \omega_{i,j}^{l-1} \quad l\geq 2, \quad \textrm{and}\quad V_{i,j}^1: \omega_{i,j}^1 \to \omega_{i,j-1}^{e_i,(p)} = \omega_{i,j-1}^{e_i, \otimes p} \end{align*}$$
by restriction to
$\omega $
. Such morphisms give sections of
$\omega _{i,j}^{l-1}\bigotimes (\omega _{i,j}^1)^{-1}$
and
$\omega _{i,j-1}^{e_i, \otimes p} \bigotimes (\omega _{i,j}^1)^{-1}$
respectively, which are the partial Hasse invariants of Reduzzi-Xiao. More precisely,
$\omega _{i,j}^l$
is just a Frobenius twisted version of
$\omega _{{\tau }_{\mathfrak {p}_i,j}^l}$
in [Reference Reduzzi and Xiao56], i.e.,
$(\omega _{i,j}^{l})^{(p)} = \omega _{{\tau }_{\mathfrak {p}_i,j}^l}$
. Now by [Reference Imai and Koskivirta27, Proposition 5.2.3], every codimension one closed Ekedahl-Oort stratum of zip stacks can be cut out from zip partial Hasse invariants. So we at least have codimension one closed EO strata coincide with those in Reduzzi-Xiao’s definition.
In the Hilbert case, any EO stratum can be cut out from codimension one strata as the associated Weyl group is isomorphic to
$({\mathbb {Z}}/2{\mathbb {Z}})^n$
. So all the EO strata of splitting models of Hilbert modular varieties coincide with the strata constructed by the partial Hasse invariants in [Reference Reduzzi and Xiao56].
4.5 Example: Hilbert-Siegel case
Let L be a totally real field over
$\mathbb {Q}$
with
$n=[L:\mathbb {Q}]>1$
and
$$\begin{align*}G = (\operatorname{\mathrm{Res}}_{L|\mathbb{Q}} \operatorname{\mathrm{GSp}}_{2g})^{\det \in \mathbb{Q}^\times}\end{align*}$$
the similitude subgroup of
$\operatorname {\mathrm {Res}}_{L|\mathbb {Q}} \operatorname {\mathrm {GSp}}_{2g}$
. In fact one can also work with Shimura varieties associated to the sightly larger group
$\operatorname {\mathrm {Res}}_{L|\mathbb {Q}} \operatorname {\mathrm {GSp}}_{2g}$
, which is of abelian type, by taking some suitable group quotient which does not change the geometry at p, see, for example, [Reference Boxer, Calegari, Gee and Pilloni8, Reference Shen and Zhang61, Reference Emerton, Reduzzi and Xiao16, Reference Kret and Shin31]. Fix a prime to p level
$K^p\subset G(\mathbb {A}_f^p)$
which is sufficiently small. Let
${\mathscr {A}}^{\mathrm {spl}}$
be the splitting model over
${\mathcal {O}}_F$
corresponding to G. Note that when
$g=1$
, we return to the Hilbert case in the last subsection.
As
$L = B$
, we have
$$\begin{align*}L \otimes_{{\mathbb{Q}}} {\mathbb{Q}}_p \simeq \prod_{i=1}^r F_i\end{align*}$$
and
$$\begin{align*}{\mathcal{G}}_0^{\mathrm{spl}} \subset \prod_{i=1}^r (\operatorname{\mathrm{Res}}_{\kappa_i | {\mathbb{F}}_p} \operatorname{\mathrm{GSp}}_{2g})^{e_i}.\end{align*}$$
Recall that the EO index set of
$\operatorname {\mathrm {GSp}}_{2g}$
is
$\{0,1\}^g$
(see [Reference Viehmann and Wedhorn65, §5.4]), so the EO index set
$^J W$
of
${\mathscr {A}}_0^{\mathrm {spl}}$
can be identified with
$(\{0,1\}^g)^n$
, under the isomorphism
${\mathcal {G}}_{0,\kappa ,der}^{\mathrm {spl}} \otimes _{{\mathbb {F}}_p} k \simeq (\mathrm {Sp}_{2g})^n$
. Given
$x = (\underline {A}, \underline {{\mathscr {F}}_{\bullet }}) \in {\mathscr {A}}_0^{\mathrm {spl}}(k)$
, the EO type of x can be written as a tuple
$a = (a_{i,j}^l)$
, where
$a_{i,j}^l \in \{0,1\}^g$
. For each index
$i,j,l$
, by the construction in subsection 3.2 at the point x, we have an F-zip structure at the standard tuple
$(\Lambda _{i,j}^l \otimes \kappa , C_{0,i,j}^l, D_{0,i,j}^l)$
(of type
$\mu _{i,j}^l$
) by trivializing the filtrations
$$\begin{align*}{\mathcal{M}}_{i,j}^l \supset C_{i,j}^l \supset 0, \quad \text{ and }\quad 0 \subset D_{i,j}^l \subset {\mathcal{M}}_{i,j}^{l+1}.\end{align*}$$
The classification of F-zips of type
$\mu _{i,j}^l$
is given by the set
$\{0,1\}^g$
. This gives the element
$a=(a_{i,j}^l)\in (\{0,1\}^g)^n$
with respect to x.
We give a description of the
$\mu $
-ordinary Hasse invariants. For each i and
$l \geq 2$
, we have defined a map
$V_i^{l}: {\mathcal {M}}_i^l \to {\mathcal {M}}_i^{l-1}$
, which reduces to a morphism
$$\begin{align*}V_i^l: \omega_i^{l} \to \omega_i^{l-1}, \quad\text{ where }\quad \omega_i^{l} := \bigoplus_j C_{i,j}^{l}.\end{align*}$$
For
$l = 1$
, we have the morphism
$$\begin{align*}V_i^1: \omega_i^{1} \to (\omega_i^{e_i})^{\otimes p}.\end{align*}$$
Taking summation induces a morphism
$$\begin{align*}\det(V_i): \det(\omega_i^{1}) \bigotimes \cdots \bigotimes \det(\omega_i^{e_i}) \to \det(\omega_i^{1}) \bigotimes \cdots \bigotimes \det(\omega_i^{e_i-1}) \bigotimes \det(\omega_i^{e_i})^{\otimes p}, \end{align*}$$
and a global section
$$\begin{align*}h_i \in H^0({\mathscr{A}}_0^{\mathrm{spl}}, \det(\omega_i^{e_i})^{\otimes (p-1)}).\end{align*}$$
Let h be the product of the
$h_i$
, which is a section of the product of the line bundles
$\det (\omega _i^{e_i})^{\otimes (p-1)}$
. It coincides with the
$\mu $
-ordinary Hasse invariant coming from the zip stack.
4.6 Example: Unitary Shimura varieties
Let
$L^+$
be a totally real field and
$L|L^+$
a totally imaginary quadratic extension. We denote by
$c\in \textrm {Gal}(L/L^+)$
the nontrivial element. Let
$I=\operatorname {\mathrm {Hom}}(L^+,\overline {\mathbb {Q}})$
and for any
$\sigma \in I$
we fix a choice of extension
$\tau : L\rightarrow \overline {\mathbb {Q}}$
of
$\sigma $
. Then we have
$\operatorname {\mathrm {Hom}}(L,\overline {\mathbb {Q}})=I\coprod I\circ c$
.
Let V be an L-vector space of dimension n together with a hermitian form
$\langle \cdot ,\cdot \rangle $
. We assume that this form is not totally definite. Let
$G=GU(V,\langle \cdot ,\cdot \rangle )$
be the associated reductive group of unitary similitudes over
$\mathbb {Q}$
. Let
$(p_\tau ,q_\tau )_{\tau \in I}$
be the signature of
$G_{\mathbb {R}}$
so that
$G_{\mathbb {R}}=G(\prod _{\tau \in I}U(p_\tau ,q_\tau ))$
and we get a standard
$h: \operatorname {\mathrm {Res}}_{\mathbb {C}|\mathbb {R}}\mathbb {G}_m\rightarrow G_{\mathbb {R}}$
. If we write
$G_1=U(V,\langle \cdot ,\cdot \rangle )$
as the corresponding unitary group over
$\mathbb {Q}$
, then
$G_1=\operatorname {\mathrm {Res}}_{L^+|\mathbb {Q}}U$
, where U is the unitary group over
$L^+$
defined by
$(V,\langle \cdot ,\cdot \rangle )$
.
Let
$p>2$
be a prime and
$\Lambda \subset V_{\mathbb {Q}_p}$
be a PEL
${\mathcal {O}}_L$
-lattice. We get a parahoric group scheme
$\mathcal {G}$
over
$\mathbb {Z}_p$
. Let
$v_1,\cdots ,v_r$
be the places of
$L^+$
over p. For each
$v_i$
, as in subsection 2.1, we assume that
$v_i$
is unramified in L, thus we have the following two cases:
-
• (AL):
$v_i$
splits in L, -
• (AU):
$v_i$
is inert in L.
Fix a tame level
$K^p\subset G(\mathbb {A}_f^p)$
and let
$K=\mathcal {G}(\mathbb {Z}_p)K^p$
. Let E be the local reflex field and
$F|\mathbb {Q}_p$
a sufficiently large field extension as before. We get integral models over
${\mathcal {O}}_F$
of the associated PEL moduli space
${\mathscr {A}}_K^{\mathrm {spl}}\rightarrow {\mathscr {A}}_K\otimes _{{\mathcal {O}}_E}{\mathcal {O}}_F$
.
Over the algebraically closed field k, the group
${\mathcal {G}}_{0,k}^{\mathrm {spl}}$
is just the associated similitude subgroup of
$$ \begin{align*}\prod_{i,j,l} \operatorname{\mathrm{GL}}_{d_i}\times {\mathbb{G}}_m.\end{align*} $$
Moreover, the cocharacter has a decomposition
$\mu = \prod _{i,j,l} \mu _{i,j}^l$
, where each
$\mu _{i,j}^l$
has type
$(d_{i,j}^l,d_i - d_{i,j}^l)$
, corresponding to some
$(p_\tau , q_\tau )$
above. By the classification of F-zips in [Reference Moonen and Wedhorn43] and the decomposition of
${\mathcal {G}}_0^{\mathrm {spl}}$
, the EO index set
$^J W$
decomposes as
$$\begin{align*}^J W = \prod_{i,l} W_{i}^l, \quad\textrm{ where }\quad W_i^l \simeq \prod_{1 \leq j \leq f_i} (S_{d_{i,j}^l} \times S_{d_i - d_{i,j}^l})\setminus S_{d_i},\end{align*}$$
where
$S_{d_i}$
is the permutation group of
$d_i$
elements, and
$(S_{d_{i,j}^l} \times S_{d_i - d_{i,j}^l})$
is the subgroup of
$S_{d_i}$
consisting of the permutations of the first
$d_{i,j}^l$
elements and the permutations of the last
$d_i - d_{i,j}^l$
elements. For a precise description of the minimal length representatives for the left coset
$(S_{d_{i,j}^l} \times S_{d_i - d_{i,j}^l})\setminus S_{d_i}$
, see [Reference Moonen and Wedhorn43] subsection 2.6. The partial order
$\preceq $
on
$^J W$
is given by the product of the partial orders on
$W_{i}^l$
. We remark that different types of i induce different Frobenius actions on
$W_i^l$
, which induces different partial orders
$\preceq $
on
$W_i^l$
. The construction of Hasse invariants is the same as above.
5 Extensions to compactifications
To study applications to cohomology, we need to extend the previous constructions to compactifications. In other words, we need to study the degeneration of F-zips with additional structure on splitting models. Fortunately, the arithmetic compactifications for general splitting models have already been established by Lan in [Reference Lan37]. Here we single out the special case of smooth splitting models. It turns out the properties of these compactifications are as good as those in the unramified setting [Reference Lan33].
5.1 Modifications of moduli spaces and integral models
Before talking about compactifications of splitting models, we need to slightly modify our integral models following [Reference Lan37]. Recall we have fixed a tame level
$K^p\subset G(\mathbb {A}_f^p)$
and
$K=K^p\mathcal {G}(\mathbb {Z}_p)$
. Let
$\mathsf {M}_K$
be the integral model over
${\mathcal {O}}_E$
constructed as in [Reference Lan35] (denoted by
$\overrightarrow {\mathsf {M}}_{\mathcal {H}}$
in [Reference Lan35, Reference Lan36, Reference Lan37], where
$\mathcal {H}$
denotes the level as in loc. cit.). Then we get an open and closed embedding (cf. [Reference Lan37] Corollary 2.4.8) of
${\mathcal {O}}_E$
-schemes
$$\begin{align*}\mathsf{M}_K\hookrightarrow{\mathscr{A}}_{K^p},\end{align*}$$
thus composing with the closed immersion
${\mathscr {A}}_{K^p}\subset {\mathscr {A}}^{\operatorname {\mathrm {naive}}}_{K^p}$
we get also a closed immersion
$\mathsf {M}_K\subset {\mathscr {A}}^{\operatorname {\mathrm {naive}}}_{K^p}$
. On generic fibers, we have an open and closed embedding of E-schemes (cf. [Reference Lan33] Lemma 1.4.4.2)
$$\begin{align*}\mathsf{M}_{K,E}\hookrightarrow{\mathscr{A}}_{K^p,E}.\end{align*}$$
Let
$(\underline {\mathcal {H}},\underline {{\mathscr {F}}}, \underline {\iota })$
be the polarized
${\mathcal {O}}_B\otimes {\mathcal {O}}_{\mathsf {M}_K}$
-modules (see Definition A.3) associated to the pullback of the universal object over
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
. Here in fact
${\mathscr {F}}=\omega $
. By the notation of [Reference Lan37] Proposition 2.3.10, we define the corresponding splitting model as the moduli scheme of splitting structures of
$(\underline {\mathcal {H}},\underline {{\mathscr {F}}}, \underline {\iota })$
over
$\mathsf {M}_K\otimes {\mathcal {O}}_F$
$$\begin{align*}\mathsf{M}_K^{\mathrm{spl}}=\mathrm{Spl}^+_{(\underline{\mathcal{H}},\underline{{\mathscr{F}}},\underline{\iota})/\mathsf{M}_K\otimes {\mathcal{O}}_F}.\end{align*}$$
Then we get an induced open and closed embedding of
${\mathcal {O}}_F$
-schemes
$$\begin{align*}\mathsf{M}_K^{\mathrm{spl}}\hookrightarrow {\mathscr{A}}_{K^p}^{\mathrm{spl}}.\end{align*}$$
The difference of these schemes is bounded by the size of failure of the Hasse principle (cf. [Reference Lan33] Remark 1.4.3.12). All the results in previous sections still hold for
$\mathsf {M}_K^{\mathrm {spl}}$
and
$\mathsf {M}_K$
, as in fact our previous constructions can be done for the related integral models of the associated Shimura varieties.
5.2 Arithmetic compactifications of splitting models
We briefly review some basic properties of the toroidal and minimal compactifications of
$\mathsf {M}_K^{\mathrm {spl}}$
constructed by Lan in [Reference Lan37], which will be used in the following.
Recall that we have a morphism
$\mathsf {M}_K^{\mathrm {spl}}\rightarrow \mathsf {M}_K\otimes {\mathcal {O}}_F$
. By [Reference Lan35, Reference Lan36] we choose a toroidal compactification
$\mathsf {M}^{\mathrm {tor}}_{K,\Sigma }$
of
$\mathsf {M}_K$
over
${\mathcal {O}}_E$
associated to a compatible collection
$\Sigma $
of cone decompositions. Over
$\mathsf {M}_K$
, we have the polarized
${\mathcal {O}}_B\otimes {\mathcal {O}}_{\mathsf {M}_K}$
-modules
$(\underline {\mathcal {H}},\underline {\mathscr {F}}, \underline {\iota })$
associated to the universal abelian scheme with additional structure as above. By [Reference Lan37] Proposition 3.1.2, the triple
$(\underline {\mathcal {H}},\underline {\mathscr {F}}, \underline {\iota })$
uniquely extends to an
${\mathscr {L}}$
-set of polarized
${\mathcal {O}}_B\otimes {\mathcal {O}}_{\mathsf {M}^{\mathrm {tor}}_{K,\Sigma }}$
-modules
$(\underline {\mathcal {H}}^{\mathrm {ext}},\underline {{\mathscr {F}}}^{\mathrm {ext}}, \underline {\iota }^{\mathrm {ext}})$
. Then we define
$$\begin{align*}\mathsf{M}_{K,\Sigma}^{\mathrm{spl},\mathrm{tor}}=\mathrm{Spl}^+_{(\underline{\mathcal{H}}^{\mathrm{ext}},\underline{{\mathscr{F}}}^{\mathrm{ext}}, \underline{\iota}^{\mathrm{ext}})/\mathsf{M}^{\mathrm{tor}}_{K,\Sigma}\otimes {\mathcal{O}}_F}\end{align*}$$
as the scheme of splitting structures of
$(\underline {\mathcal {H}}^{\mathrm {ext}},\underline {{\mathscr {F}}}^{\mathrm {ext}}, \underline {\iota }^{\mathrm {ext}})$
over
$\mathsf {M}^{\mathrm {tor}}_{K,\Sigma }\otimes {\mathcal {O}}_F$
. By [Reference Lan37] Theorem 3.4.1, for suitable choice of
$\Sigma $
, the scheme
$\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}$
is normal, projective and flat over
${\mathcal {O}}_F$
, and admits a similar description as the usual compactifications
$\mathsf {M}^{\mathrm {tor}}_{K,\Sigma }$
.
Proposition 5.1. For a projective smooth
$\Sigma $
, the scheme
$\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}$
is projective and smooth over
${\mathcal {O}}_F$
.
Proof. This follows from [Reference Lan37] Propositions 3.4.13, 3.4.14, and our Proposition 2.3.
Alternatively, the smoothness of
$\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}$
can also be seen from the extended local model diagram in the next subsection.
From now on we assume that
$\Sigma $
is projective and smooth. Thus the canonical morphism
$$\begin{align*}\mathsf{M}_{K,\Sigma}^{\mathrm{spl},\mathrm{tor}}\rightarrow \mathsf{M}_{K,\Sigma}^{\mathrm{tor}}\otimes {\mathcal{O}}_F\end{align*}$$
is a resolution of singularities.
By [Reference Lan37] Propositions 4.1.22, 4.2.31 and 4.2.34, we have the minimal compactification
$\mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
together with a canonical morphism
$\oint : \mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}\rightarrow \mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
, which fits into a commutative diagram of schemes over
${\mathcal {O}}_F$
:
By loc. cit. Theorem 4.3.1, the minimal compactification
$\mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
admits a similar description to
$ \mathsf {M}_K^{\mathrm {min}}$
.
Let
$Z^{\mathrm {spl}}\subset \mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
be a boundary stratum. There is a corresponding boundary stratum
$Z\subset \mathsf {M}_K^{\mathrm {min}}$
, which is an analogue of
$\mathsf {M}_K$
for some boundary PEL datum
$({\mathcal {O}}_B, \ast , \Lambda ^Z,\langle \cdot ,\cdot \rangle ^Z, h^Z)$
so that we have the tautological abelian scheme
$(B,\lambda ,\iota )$
over Z with associated
$({}^\sharp \underline {\mathcal {H}},{}^\sharp \underline {{\mathscr {F}}}, {}^\sharp \underline {\iota })$
. By construction, we have
$$\begin{align*}Z^{\mathrm{spl}}=\textrm{Spl}^+_{({}^\sharp\underline{\mathcal{H}},{}^\sharp\underline{{\mathscr{F}}}, {}^\sharp\underline{\iota})/Z\otimes {\mathcal{O}}_F}.\end{align*}$$
Attached to
$Z^{\mathrm {spl}}$
and Z, we have the following data:
-
• an admissible cone decomposition
$\Sigma _Z$
of some cone
$\mathbf {P}=\mathbf {P}_Z$
, as well as a subset
$\Sigma _Z^+$
of
$\Sigma _Z$
which forms a cone decomposition of the interior
$\mathbf {P}^+$
of
$\mathbf {P}$
. -
• an arithmetic group
$\Gamma =\Gamma _Z$
acting on
$\mathbf {P}$
and hence also on
$\Sigma _Z$
; the open cone
$\mathbf {P}^+$
and the corresponding
$\Sigma _Z^+$
are stable under the action of
$\Gamma $
. As in [Reference Lan and Stroh38] we may and we shall assume that for each
$\sigma \in \Sigma _Z^+$
, the stabilizer
$\Gamma _\sigma $
is trivial. -
• a finite free abelian group S; let
$\mathbf {E}=\mathbf {E}_Z$
be a split torus over
$\mathbb {Z}$
with character group S. -
• a normal scheme
$C^{\mathrm {spl}}$
which is flat over
${\mathcal {O}}_F$
, together with a proper surjective morphism
$C^{\mathrm {spl}}\rightarrow Z^{\mathrm {spl}}$
. -
• a morphism of schemes
$\Xi ^{\mathrm {spl}}\rightarrow C^{\mathrm {spl}}$
which is an
$\mathbf {E}$
-torsor; for each
$\sigma \in \Sigma _Z$
, we have an affine toroidal embedding
$\Xi ^{\mathrm {spl}}\hookrightarrow \Xi ^{\mathrm {spl}}(\sigma )$
over
$C^{\mathrm {spl}}$
with a closed subscheme
$\Xi _{\sigma }^{\mathrm {spl}}$
. -
• for each representative
$\sigma \in \Sigma _Z^+$
of an orbit
$[\sigma ]\in \Sigma _Z^+/\Gamma $
, let
$Z_{[\sigma ]}^{\mathrm {spl}}\subset \mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}$
be the corresponding toroidal boundary stratum, and
$\mathfrak {X}^{\mathrm {spl}}_\sigma :=(\Xi ^{\mathrm {spl}}(\sigma ))^{\wedge }_{\Xi ^{\mathrm {spl}}_{\sigma }}$
be the formal completion; then there is a canonical isomorphism of formal schemes
$$\begin{align*}\mathfrak{X}^{\mathrm{spl}}_\sigma\simeq (\mathsf{M}_{K, \Sigma}^{\mathrm{spl},\mathrm{tor}})^{\wedge}_{Z^{\mathrm{spl}}_{[\sigma]}}.\end{align*}$$
-
• let
$\Xi _Z^{\mathrm {spl}}$
be the full toroidal embedding attached to
$\Sigma _Z$
and the formal completion, then there is a canonical isomorphism
$$\begin{align*}\mathfrak{X}^{\mathrm{spl}}:=\mathfrak{X}_Z^{\mathrm{spl}}=(\Xi_Z^{\mathrm{spl}})^{\wedge}_{\quad\cup_{\tau\in\Sigma_Z^+}\Xi_{\tau}^{\mathrm{spl}}}\end{align*}$$
$$\begin{align*}\mathfrak{X}^{\mathrm{spl}}/\Gamma\simeq (\mathsf{M}_{K, \Sigma}^{\mathrm{spl},\mathrm{tor}})^{\wedge}_{\quad\cup_{\tau\in\Sigma_Z^+/\Gamma}Z_{[\tau]}^{\mathrm{spl}}}.\end{align*}$$
Note the (disjoint) union
$\cup _{\tau \in \Sigma _Z^+/\Gamma }Z_{[\tau ]}^{\mathrm {spl}}$
is exactly the preimage of
$Z^{\mathrm {spl}}$
under the natural projection
$\oint : \mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}\rightarrow \mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
. -
• there are similar and parallel objects
$C, \Xi $
, etc. for the boundary stratum Z, such that
$C^{\mathrm {spl}}=\textrm {Spl}^+_{({}^\sharp \underline {\mathcal {H}},{}^\sharp \underline {{\mathscr {F}}}, {}^\sharp \underline {\iota })/C\otimes {\mathcal {O}}_F}, \quad \Xi ^{\mathrm {spl}}=\textrm {Spl}^+_{({}^\sharp \underline {\mathcal {H}},{}^\sharp \underline {{\mathscr {F}}}, {}^\sharp \underline {\iota })/\Xi \otimes {\mathcal {O}}_F}$
, etc., see [Reference Lan37] Lemma 3.2.4.
The same arguments as in the proof of Proposition 2.3 show that
Proposition 5.2. Each boundary stratum
$Z^{\mathrm {spl}}$
is smooth over
${\mathcal {O}}_F$
.
5.3 Canonical extensions of automorphic vector bundles
Since G is split over F, it defines a reductive group scheme over
${\mathcal {O}}_F$
, denoted by
$\mathcal {G}^{\mathrm {spl}}$
(or G) as before. Moreover, recall that as in the paragraph above Corollary 2.4 the parabolic subgroup
$P_\mu $
extends to a parabolic group scheme of
$\mathcal {G}^{\mathrm {spl}}$
over
${\mathcal {O}}_F$
. Thus the flag variety
$\mathscr {F}\ell (G,\mu )_F$
extends canonically to a smooth scheme
$\mathcal {G}^{\mathrm {spl}}/P_\mu $
(the integral flag variety) over
${\mathcal {O}}_F$
which is nothing else but
$\prod _{i\in I, 1\leq j\leq f_i, 1\leq l \leq e_i}\mathbb {M}_{i,j}^l$
. We still denote by
$\mathscr {F}\ell (G,\mu )$
the integral flag variety over
${\mathcal {O}}_F$
.
Now we have an extension of the local model diagram of schemes over
${\mathcal {O}}_F$
:
where
$\pi $
is a
${\mathcal {G}}^{\mathrm {spl}}$
-torsor and q is
${\mathcal {G}}^{\mathrm {spl}}$
-equivariant. For any representation
$(V,\eta )\in \mathrm {Rep}_{{\mathcal {O}}_F}P_\mu $
, we get the associated G-equivariant vector bundle
$\underline {V}$
on
$\mathscr {F}\ell (G,\mu )$
. Via the above diagram, we get a vector bundle
$\mathcal {V}^{\mathrm {can}}=\mathcal {V}_\eta ^{\mathrm {can}}$
on
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma }$
, which we call the canonical extension of the vector bundle
$\mathcal {V}=\mathcal {V}_\eta $
on
$\mathsf {M}_K^{\mathrm {spl}}$
. Let
$D'$
be the effective Cartier divisor of [Reference Lan37] Corollary 4.4.4 with
$D^{\prime }_{red}=\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma }\setminus \mathsf {M}_K^{\mathrm {spl}}$
and set
$\mathcal {V}^{\mathrm {sub}}=\mathcal {V}^{\mathrm {can}}(-D')$
, which we call the subcanonical extension of
$\mathcal {V}=\mathcal {V}_\eta $
.
Let
$\eta \in X^\ast (T)^+_L$
and
$V\in \mathrm {Rep}_{{\mathcal {O}}_F}L$
the irreducible representation of L of highest weight
$\eta $
. Recall the map
$\oint : \mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma }\rightarrow \mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
.
Proposition 5.3. For any
$i>0$
, we have
$R^i\oint _{\ast }\mathcal {V}_\eta ^{\mathrm {sub}}=0$
.
Proof. This will follow from [Reference Lan37] Theorem 4.4.9, once we have verified that
$\mathcal {V}^{\mathrm {can}}=\mathcal {V}_\eta ^{\mathrm {can}}$
is formally canonical in the sense of loc. cit. (The definition of this notion there is given by the corresponding analogue of [Reference Lan36] Definition 8.5.) Recall that this means: for any boundary stratum
$Z^{\mathrm {spl}}$
of
$\mathsf {M}_K^{\mathrm {spl},\mathrm {min}}$
, and any geometric point
$\overline {x}$
over
$Z^{\mathrm {spl}}$
, there exists a coherent sheaf
$ \mathcal {V}_{0,\overline {x}}$
over
$C_{\overline {x}}^{\mathrm {spl},\wedge }$
such that
-
(1) for any
$\sigma \in \Sigma _Z^+$
, the pullback
$\mathcal {V}^{\mathrm {can},\wedge }$
to
$\mathfrak {X}_{\sigma ,\overline {x}}^\wedge $
is of the form
$$\begin{align*}\widehat{\bigoplus}_{\ell\in\sigma^\vee}\Big((\Psi^{\mathrm{spl}}_Z(\ell))^{\wedge}_{\overline{x}}\otimes\mathcal{V}_{0,\overline{x}}\Big),\end{align*}$$
-
(2)
$\mathcal {V}_{0,\overline {x}}$
admits a finite filtration whose graded pieces are isomorphic to pullbacks of quasi-coherent sheaves over
${\mathcal {O}}_F$
via the structural morphism
$C_{\overline {x}}^{\mathrm {spl},\wedge }\rightarrow \operatorname {\mathrm {Spec}}\,{\mathcal {O}}_F$
.
One needs to check that in the smooth reduction case the sheaf
$\mathcal {V}^{\mathrm {can}}$
satisfies the above two conditions. This can be achieved by modifying the arguments in the proof of [Reference Lan34] Proposition 5.6, where we take account of the splitting structures everywhere.
5.4 Extensions of
$\mathcal {G}_0^{\mathrm {spl}}$
-zips and Hasse invariants
Recall that
$\kappa $
is the residue field of
${\mathcal {O}}_F$
and
$k=\overline {\kappa }$
. Let
$\mathsf {M}^{\mathrm {spl}}_{K,0}=\mathsf {M}^{\mathrm {spl}}_{K}\otimes _{{\mathcal {O}}_F} k$
,
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}=\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma }\otimes _{{\mathcal {O}}_F} k$
and
$\mathsf {M}^{\mathrm {spl},\mathrm {min}}_{K,0}=\mathsf {M}^{\mathrm {spl},\mathrm {min}}_{K}\otimes _{{\mathcal {O}}_F} k$
be the geometric special fibers. By section 3 we have a smooth surjective morphism
$$\begin{align*}\zeta: \mathsf{M}^{\mathrm{spl}}_{K,0}\rightarrow {\mathcal{G}}^{\mathrm{spl}}_0\textrm{-}\mathrm{Zip}^\mu_k.\end{align*}$$
Before discussing extensions of zips to the boundary, we need some group theoretical preparation. For each
$Z^{\mathrm {spl}}\subset \mathsf {M}^{\mathrm {spl},\mathrm {min}}_{K}$
and the associated
$Z\subset \mathsf {M}^{\mathrm {min}}_K$
, recall that we have the boundary PEL-type
${\mathcal {O}}_B$
-lattice
$(\Lambda ^Z, \langle \cdot ,\cdot \rangle ^Z,h^Z)$
. Over
$\mathbb {Q}$
, we have the associated parabolic subgroups
$$\begin{align*}Q=Q_Z\subset P=P_Z\subset G,\end{align*}$$
cf. [Reference Lan and Stroh38] Lemma 3.3.6 and Definition 3.3.8. More precisely, attached to the boundary stratum
$Z\subset \mathsf {M}^{\mathrm {min}}_K$
we have a symplectic filtration
$0\subset V_{-2}\subset V_{-1}\subset V_0=V$
satisfying the condition as in Lemma 3.3.6 of [Reference Lan and Stroh38]. The group
$P=P_Z$
is defined as the stabilizer of this filtration. The group
$Q=Q_Z$
is defined as the kernel of the homomorphism
$P\rightarrow \operatorname {\mathrm {GL}}(gr_{-2}V)\times \operatorname {\mathrm {GL}}(gr_{0}V),\; (g,r)\mapsto (r^{-1}gr_{-2}(g),gr_0(g))$
, where
$P\rightarrow \mathbb {G}_m, \; (g,r)\mapsto r$
is the similitude character. The groups P and Q have the same unipotent radical U, such that
$M_h:=Q/U$
is the reductive group for the rational PEL datum corresponding to Z, and
$M:=P/U=M_h\times M_l$
, where
$M_l\simeq P/Q$
is a reductive group factor of the Levi M, see [Reference Lan and Stroh38] Definition 3.3.8.
Consider the reductive group
$\mathcal {G}_0^{\mathrm {spl}}$
over
${\mathbb {F}}_p$
. We want to adapt the construction of [Reference Andreatta2] subsection 3.3 to our setting. Consider the induced symplectic filtration
$$\begin{align*}0\subset \Lambda_{-2}\subset \Lambda_{-1}\subset \Lambda_0=\Lambda\end{align*}$$
so that
$$\begin{align*}\Lambda^Z=gr_{-1}\Lambda=\Lambda_{-1}/\Lambda_{-2},\end{align*}$$
and the decomposition
$\Lambda =\bigoplus _{1 \leq i \leq r} \Lambda _i^{m_i}$
, we get similar filtrations on each
$\Lambda _i$
. Using the fact that each
$\Lambda _i$
is self-dual over
${\mathcal {O}}_{F_i}$
, by similar construction as in subsection 2.1, we have parabolic subgroups
$$\begin{align*}\mathcal{Q}_0^{\mathrm{spl}}\subset \mathcal{P}_0^{\mathrm{spl}}\subset \mathcal{G}_0^{\mathrm{spl}} \end{align*}$$
with the same unipotent radical
$U^{\mathrm {spl}}_0$
. Let
$M^{\mathrm {spl}}_0=\mathcal {P}_0^{\mathrm {spl}}/U^{\mathrm {spl}}_0$
and
$M^{\mathrm {spl}}_{h,0}=\mathcal {Q}_0^{\mathrm {spl}}/U^{\mathrm {spl}}_0$
. Then
$M^{\mathrm {spl}}_0=M^{\mathrm {spl}}_{h,0}\times M^{\mathrm {spl}}_{l,0}$
, where
$M^{\mathrm {spl}}_{l,0}=\mathcal {P}_0^{\mathrm {spl}}/\mathcal {Q}_0^{\mathrm {spl}}$
. Recall that we have the cocharacter
$\mu $
of
$\mathcal {G}_0^{\mathrm {spl}}$
which is defined over
$\kappa $
, and
$P_+:=P_\mu \subset \mathcal {G}_{0,\kappa }^{\mathrm {spl}}$
the associated parabolic subgroup. Set
$\overline {P}:= \mathcal {P}_{0,\kappa }^{\mathrm {spl}} \cap P_+$
. We get the inclusions
$$\begin{align*}\overline{P}\subset P_+\subset \mathcal{G}_{0,\kappa}^{\mathrm{spl}}.\end{align*}$$
Consider the induced cocharacter
$\mu _Z$
of
$M^{\mathrm {spl}}_{h,0}$
from
$h^Z$
. We get a natural morphism
$$\begin{align*}\gamma: M^{\mathrm{spl}}_{h,0}\textrm{-Zip}^{\mu_Z}_\kappa\rightarrow M^{\mathrm{spl}}_{0}\textrm{-Zip}^{\mu_Z}_\kappa,\end{align*}$$
where we denote by the same notation
$\mu _Z$
for the induced cocharacter of
$M^{\mathrm {spl}}_{0}$
. Identifying
$M^{\mathrm {spl}}_{0}$
as the standard Levi of
$\mathcal {P}_0^{\mathrm {spl}}$
, the inclusion
$M^{\mathrm {spl}}_{0}\subset \mathcal {G}_0^{\mathrm {spl}}$
induces a morphism
$$\begin{align*}\upsilon: M^{\mathrm{spl}}_{0}\textrm{-Zip}^{\mu_Z}_\kappa\rightarrow [E_{\overline{\mathcal{Z}}}\setminus \mathcal{G}_{0,\kappa}^{\mathrm{spl}}],\end{align*}$$
where
$\overline {\mathcal {Z}}=(\overline {P}, \overline {P}^{(p)}, \varphi )$
is the algebraic zip data for
$\mathcal {G}_{0,\kappa }^{\mathrm {spl}}$
associated to
$\overline {P}$
. Then the natural inclusion
$\overline {P}\subset P_+$
induces a morphism
$$\begin{align*}\epsilon: [E_{\overline{\mathcal{Z}}}\setminus \mathcal{G}_{0,\kappa}^{\mathrm{spl}}]\rightarrow \mathcal{G}^{\mathrm{spl}}_0\textrm{-}\mathrm{Zip}^\mu_\kappa.\end{align*}$$
We define
$$\begin{align*}{\tau}_Z=\epsilon\circ\upsilon\circ\gamma: M^{\mathrm{spl}}_{h,0}\textrm{-Zip}^{\mu_Z}_\kappa\rightarrow \mathcal{G}^{\mathrm{spl}}_0\textrm{-}\mathrm{Zip}^\mu_\kappa.\end{align*}$$
In the following we also write
$\mathcal {G}^{\mathrm {spl}}_{Z,0}=M^{\mathrm {spl}}_{h,0}$
to indicate its analogue with
$\mathcal {G}^{\mathrm {spl}}_0$
.
Given the canonical extensions of automorphic vector bundles to
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}$
, the constructions of subsection 3.2 can be generalized.
Theorem 5.4.
-
(1) The
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip of type
$\mu $
on
$\mathsf {M}^{\mathrm {spl}}_{K,0}$
extends to a
$G({\mathbb {A}}_f^p)$
-equivariant
${\mathcal {G}}^{\mathrm {spl}}_0$
-zip of type
$\mu $
on
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}$
. -
(2) The induced map
$\zeta ^{\mathrm {tor}}: \mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}\rightarrow {\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _k$
is smooth.
Proof. For (1), we just repeat the construction in subsection 3.2 starting from
$(\underline {\mathcal {H}}^{\mathrm {ext}},\underline {{\mathscr {F}}}^{\mathrm {ext}}, \underline {\iota }^{\mathrm {ext}})$
together with its universal splitting structure.
For (2), we follow the idea in the proof of [Reference Andreatta2] Theorem 3.1. Let
$x\in \mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}$
be a closed point and
$C=\widehat {{\mathcal {O}}}_{\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0},x}$
. We need only check that the induced morphism
$$\begin{align*}\zeta_C: \operatorname{\mathrm{Spec}}\,C\rightarrow {\mathcal{G}}^{\mathrm{spl}}_0\textrm{-}\mathrm{Zip}^\mu_k\end{align*}$$
is smooth. If
$x\in \mathsf {M}^{\mathrm {spl}}_{K,0}$
, this has been done in Proposition 3.10. So we may assume that
$x\in Z_{[\sigma ]}^{\mathrm {spl}}$
for a boundary stratum. Then there is a corresponding point
$x'\in \Xi ^{\mathrm {spl}}(\sigma )$
such that
$C=\widehat {{\mathcal {O}}}_{\Xi ^{\mathrm {spl}}(\sigma ),x'}$
. Let
$y\in Z^{\mathrm {spl}}$
be the image of x and
$D=\widehat {{\mathcal {O}}}_{Z^{\mathrm {spl}},y}$
. We get an induced morphism
$$\begin{align*}\oint: \operatorname{\mathrm{Spec}}\,C\rightarrow \operatorname{\mathrm{Spec}}\,D.\end{align*}$$
Moreover, we have the boundary version
$\zeta _Z: Z^{\mathrm {spl}}\rightarrow \mathcal {G}_{0,Z}^{\mathrm {spl}}\textrm {-Zip}^{\mu _Z}_k$
and the analogue
$$\begin{align*}\zeta_D: \operatorname{\mathrm{Spec}}\,D\rightarrow \mathcal{G}_{0,Z}^{\mathrm{spl}}\textrm{-Zip}^{\mu_Z}_k\end{align*}$$
of
$\zeta _C$
. Recall that by Proposition 5.2,
$Z^{\mathrm {spl}}$
is smooth. We have also a natural morphism
$$\begin{align*}{\tau}_Z: \mathcal{G}_{0,Z}^{\mathrm{spl}}\textrm{-Zip}^{\mu_Z}_\kappa\rightarrow {\mathcal{G}}^{\mathrm{spl}}_0\textrm{-}\mathrm{Zip}^\mu_\kappa.\end{align*}$$
To show the smoothness of
$\zeta _C: \operatorname {\mathrm {Spec}}\,C\rightarrow {\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _\kappa $
, we proceed in four steps.
Step 1. We show
$\zeta _C={\tau }_Z\circ \zeta _D\circ \oint $
. In other words, the following diagram commutes:
We need to analyze the structure of the
$\mathcal {G}_0^{\mathrm {spl}}$
-zip on C in terms of the associated
$\mathcal {G}_{0,Z}^{\mathrm {spl}}$
-zip. Consider the restriction of
$(\underline {\mathcal {H}}^{\mathrm {ext}},\underline {{\mathscr {F}}}^{\mathrm {ext}}, \underline {\iota }^{\mathrm {ext}})$
on
$Z_{[\sigma ]}^{\mathrm {spl}}$
, which we denote by
$(\underline {\mathcal {H}}^\natural ,\underline {{\mathscr {F}}}^\natural , \underline {\iota }^\natural )$
. By [Reference Lan37] proof of Proposition 3.3.21, there are isomorphisms
$$\begin{align*}{\mathscr{F}}^\natural\simeq {}^\sharp {\mathscr{F}}\oplus {}^\flat{\mathscr{F}}, \quad \textrm{where} \quad {}^\flat{\mathscr{F}}=\omega_{T^\vee/Z_{[\sigma]}}.\end{align*}$$
Moreover, the filtration
$\underline {{\mathscr {F}}_{\bullet }}^\natural $
on
${\mathscr {F}}^\natural $
induces filtrations on
$ {}^\sharp {\mathscr {F}}$
and
${}^\flat {\mathscr {F}}$
as [Reference Lan37] Lemma 3.3.11, and by loc. cit. Corollary 3.3.16 the filtration on
${}^\flat {\mathscr {F}}$
is independent of the filtration on
${\mathscr {F}}^\natural $
. By the construction in section 3, the F-zip
$\mathcal {M}^\natural $
(constructed from
$(\underline {\mathcal {H}}^\natural ,\underline {{\mathscr {F}}}^\natural , \underline {\iota }^\natural )$
) is a direct sum of the F-zip
$\mathcal {M}_Z$
constructed from
$({}^\sharp \underline {\mathcal {H}},{}^\sharp \underline {{\mathscr {F}}}, {}^\sharp \underline {\iota })$
and the F-zip constructed from
${}^\flat {\mathscr {F}}$
. Translating further into the language of
${\mathcal {G}}^{\mathrm {spl}}_0$
-zips, we have the factorization of
$\zeta _C$
.
Step 2.
$\oint : \operatorname {\mathrm {Spec}}\,C\rightarrow \operatorname {\mathrm {Spec}}\,D$
is smooth. For this, we apply the local diagrams for
$\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma }$
and
$Z^{\mathrm {spl}}$
to realize C and D as local rings of the corresponding local models, which are also completions along identities of some unipotent subgroups, see the proof of Proposition 3.10. Then one can prove the smoothness of
$\oint $
by checking that on tangent spaces it induces a projection.
Step 3.
$\zeta _D: \operatorname {\mathrm {Spec}}\,D\rightarrow \mathcal {G}_{0,Z}^{\mathrm {spl}}\textrm {-Zip}^{\mu _Z}_k$
is smooth. As
$Z^{\mathrm {spl}}$
is smooth, the smoothness of
$\zeta _D$
follows from the boundary version of Proposition 3.10.
Step 4.
${\tau }_Z: \mathcal {G}_{0,Z}^{\mathrm {spl}}\textrm {-Zip}^{\mu _Z}_k\rightarrow {\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _k$
is smooth. This follows from a similar argument as the proof of [Reference Andreatta2] Lemma 3.4.
We write
$X^{\mathrm {tor}}=\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma ,0}$
and the fiber of
$\zeta ^{\mathrm {tor}}$
at w as
$X^{\mathrm {tor}}_w$
. Then we get the EO stratification
$$\begin{align*}X^{\mathrm{tor}}=\coprod_{w\in {}^JW}X^{\mathrm{tor}}_w.\end{align*}$$
For each
$w\in {}^JW$
let
$\overline {X^{\mathrm {tor}}_w}$
be the Zariski closure of
$X^{\mathrm {tor}}_w$
in
$X^{\mathrm {tor}}$
.
Corollary 5.5. The Hasse invariant
$h_w\in H^0(\overline {X_w}, \omega _{\operatorname {\mathrm {Hdg}}}^{N_w})$
of Corollary 4.7 extends to a
$G({\mathbb {A}}_f^p)$
-equivariant section
$h_w^{\mathrm {tor}} \in H^0(\overline {X^{\mathrm {tor}}_w}, \omega _{\operatorname {\mathrm {Hdg}}}^{N_w})$
with non-vanishing locus being precisely
$X_w^{\mathrm {tor}}$
.
The proof of Theorem 5.4 (2) actually gives us the following (expected) description of
$\zeta ^{\mathrm {tor}}$
on the boundary. Let
$Z_0^{\mathrm {spl}}\subset \mathsf {M}^{\mathrm {spl},\mathrm {min}}_{K,0}$
be a boundary stratum and
$Z_0^{\mathrm {spl},\mathrm {tor}}:=\oint ^{-1}(Z_0^{\mathrm {spl}})$
. We get an induced morphism
$\oint : Z_0^{\mathrm {spl},\mathrm {tor}}\rightarrow Z_0^{\mathrm {spl}}$
.
Proposition 5.6. The restriction
$$\begin{align*}\zeta^{\mathrm{tor}}|_{Z_0^{\mathrm{spl},\mathrm{tor}}}= {\tau}_Z\circ\zeta_Z\circ\oint,\end{align*}$$
where
${\tau }_Z$
and
$\zeta _Z$
are as in the proof of Theorem 5.4 (2).
Corollary 5.7. Let
$e\in {}^JW$
be the minimal element (then
$\ell (e)=0$
). The associated EO stratum
$X_e$
does not intersect with the boundary of
$X^{\mathrm {tor}}$
, in other words, we have
$X_e=X_e^{\mathrm {tor}}$
. In particular, the conclusions of Proposition 4.5 hold for
$X^{\mathrm {tor}}$
.
Proof. Similar to [Reference Andreatta2] Corollary 3.7, this follows from the fact that for each boundary Z,
${\tau }_Z: \mathcal {G}_{0,Z}^{\mathrm {spl}}\textrm {-Zip}^{\mu _Z}_k\rightarrow {\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _k$
is smooth, thus open, therefore its image does not contain the closed point of
${\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _k$
. Indeed, if its image contained the closed point, it would be surjective and any maximal chain of points of
$|{\mathcal {G}}^{\mathrm {spl}}_0\textrm {-}\mathrm {Zip}^\mu _k|$
would be the image of a maximal chain of points of
$|\mathcal {G}_{0,Z}^{\mathrm {spl}}\textrm {-Zip}^{\mu _Z}_k|$
. This is impossible since
$\dim \,Z<\dim \,X$
with
$X=\mathsf {M}^{\mathrm {spl}}_{K,0}$
(see also the proof of [Reference Andreatta2] Corollary 3.7).
Next, we discuss the well-positionedness of EO strata in the sense of [Reference Lan and Stroh38] Definition 2.2.1, which is in fact closely related to the smoothness of
$\zeta ^{\mathrm {tor}}$
. Let
$Z^{\mathrm {spl}}$
be a boundary stratum of
$\mathsf {M}^{\mathrm {spl},\mathrm {min}}_{K}$
. Recall for each
$\sigma \in \Sigma _Z^+$
, we have
$\Xi ^{\mathrm {spl}}(\sigma )$
and its closed subscheme
$\Xi ^{\mathrm {spl}}_{\sigma }$
. Consider the closed subscheme
$$\begin{align*}\Xi^{\mathrm{spl}}(\sigma)^+:=\cup_{\tau\in\Sigma_Z^+,\overline{\tau}\subset\overline{\sigma}}\Xi^{\mathrm{spl}}_\tau\end{align*}$$
and the formal completion
$$\begin{align*}\mathfrak{X}_\sigma^{\mathrm{spl},\circ}:=(\Xi^{\mathrm{spl}}(\sigma))^\wedge_{\Xi^{\mathrm{spl}}(\sigma)^+}.\end{align*}$$
By [Reference Lan and Stroh38] Proposition 2.1.3, the formal scheme
$\Xi ^{\mathrm {spl}}_Z$
admits an open covering by
$\mathfrak {X}_\sigma ^{\mathrm {spl},\circ }$
for
$\sigma $
running through elements of
$\Sigma _Z^+$
, and for each
$\sigma $
we have an isomorphism
$$\begin{align*}\mathfrak{X}_\sigma^{\mathrm{spl},\circ}\simeq (\mathsf{M}_{K, \Sigma}^{\mathrm{spl},\mathrm{tor}})^\wedge_{\quad\cup_{\tau\in\Sigma_Z^+,\overline{\tau}\subset\overline{\sigma}}Z_{[\tau]}}.\end{align*}$$
For any open affine formal subscheme
$\mathrm {Spf}\,R$
of
$\mathfrak {X}_\sigma ^{\mathrm {spl},\circ }$
, let
$\mathbf {W}=\operatorname {\mathrm {Spec}}\,R$
, then we get induced morphisms
$$\begin{align*}\mathbf{W}\rightarrow \mathsf{M}_{K, \Sigma}^{\mathrm{spl},\mathrm{tor}}, \quad \mathbf{W}\rightarrow \Xi^{\mathrm{spl}}(\sigma).\end{align*}$$
By these morphisms, the two stratifications of
$\mathbf {W}$
induced respectively by those of
$\mathsf {M}_{K, \Sigma }^{\mathrm {spl},\mathrm {tor}}$
and
$\Xi ^{\mathrm {spl}}(\sigma )$
coincide. Let
$$\begin{align*}\mathbf{W}^0\subset \mathbf{W}\end{align*}$$
be the open stratum, which is the preimage of
$\mathsf {M}_{K}^{\mathrm {spl}}$
and
$\Xi ^{\mathrm {spl}}$
under the above morphisms. Now consider the geometric special fiber
$\mathsf {M}_{K, \Sigma ,0}^{\mathrm {spl},\mathrm {tor}}$
and we denote by the same notations
$Z^{\mathrm {spl}}, C^{\mathrm {spl}}, \Xi ^{\mathrm {spl}}, \mathbf {W}$
, etc. the corresponding objects base-changed to k. By [Reference Lan and Stroh38] Definition 2.2.1, a locally closed subset
$$\begin{align*}Y\subset \mathsf{M}_{K,0}^{\mathrm{spl}}\end{align*}$$
is called well-positioned if there exists a collection
$$\begin{align*}(Y_Z^\sharp)_Z\end{align*}$$
indexed by the boundary strata of
$\mathsf {M}_{K,0}^{\mathrm {spl},\mathrm {min}}$
, where
$Y_Z^\sharp \subset Z^{\mathrm {spl}}$
is a locally closed subset (which may be empty), such that for any
$\Sigma $
, any
$\sigma \in \Sigma _Z^+$
and any
$\mathrm {Spf}\,R$
as above, if
$Y_Z^\sharp \neq \emptyset $
, then under the induced morphisms
$$\begin{align*}\mathbf{W}^0\rightarrow\mathsf{M}_{K,0}^{\mathrm{spl}},\quad \mathbf{W}^0\rightarrow Z^{\mathrm{spl}}\end{align*}$$
the preimages of Y and
$Y_Z^\sharp $
in
$\mathbf {W}^0$
coincide. Here
$\mathbf {W}^0\rightarrow Z^{\mathrm {spl}}$
is the composition
$$\begin{align*}\mathbf{W}^0\rightarrow \Xi^{\mathrm{spl}}\rightarrow C^{\mathrm{spl}}\rightarrow Z^{\mathrm{spl}}.\end{align*}$$
By [Reference Lan and Stroh38] Lemma 2.2.2, it suffices to verify the condition for just one collection of cone decompositions
$\Sigma $
and some affine open covering
$\mathrm {Spf}\,R$
of each
$\mathfrak {X}_\sigma ^{\mathrm {spl},\circ }$
.
Proposition 5.8. For each
$w\in {}^JW$
, the locally closed subset
$X_w$
of
$X=\mathsf {M}_{K,0}^{\mathrm {spl}}$
is well-positioned.
Proof. We can translate [Reference Lan and Stroh38] Lemma 3.4.3 into zips. Indeed, the setting of loc. cit. includes the splitting model case. Specializing to the case of p-torsion (
$n=1$
there), we see that the triple
$(A[p], \lambda , \iota )$
determines and is determined by the isomorphism classes of
$(X, Y, \phi : Y\rightarrow X)$
and of
$(B[p], \lambda _B,\iota _B)$
. The splitting structure on
$\omega _A$
is induced by those on
$X, Y$
and
$\omega _B$
. For the torus part, the splitting structure is unique, cf. [Reference Lan37] Corollary 3.3.16. Thus by construction, the
$\mathcal {G}_0^{\mathrm {spl}}$
-zip attached to
$(A[p], \lambda , \iota )$
determines and is determined by the isomorphism classes by the
$\mathcal {G}_{0,Z}^{\mathrm {spl}}$
-zip attached to
$(B[p], \lambda _B,\iota _B)$
. See also the arguments of Step 1 in the proof of Theorem 5.4. Therefore the EO strata are well-positioned.
Remark 5.9. In [Reference Lan and Stroh38] subsection 3.5, Lan and Stroh first proved that EO strata in their case (Nm) for a good prime p are well-positioned. They then deduced that
$\zeta ^{\mathrm {tor}}$
is smooth if
$\zeta $
is, cf. loc. cit. Corollary 3.5.8. Following their idea, we sketch how to deduce the smoothness of
$\zeta ^{\mathrm {tor}}$
from Proposition 5.8 as follows:
By Proposition 3.10, each
$X_w$
is smooth. As
$X_w$
is well-positioned by Proposition 5.8, the partial toroidal compactification
$(X_{w})^{\mathrm {tor}}_\Sigma $
of
$X_w$
(in the sense of [Reference Lan and Stroh38] Definition 2.3.1 and Theorem 2.3.2) is also smooth by [Reference Lan and Stroh38] Proposition 2.3.13. By construction, we see that
$(X_{w})^{\mathrm {tor}}_\Sigma $
equals to the fiber of
$\zeta ^{\mathrm {tor}}$
at w. As each fiber of
$\zeta ^{\mathrm {tor}}$
is smooth, we get
$\zeta ^{\mathrm {tor}}$
is smooth once we know it is flat. The actual argument of [Reference Lan and Stroh38] (proof of Corollary 3.5.8 there) says that étale locally
$\zeta ^{\mathrm {tor}}$
factors through
$C^{\mathrm {spl}}$
(and
$Z^{\mathrm {spl}}$
), which follows from Proposition 5.8.
6 Application to Galois representations
In this section we study the coherent cohomology of the smooth schemes
$\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}$
. We deduce some consequences for Hecke algebras and Galois representations following the same treatments of [Reference Goldring and Koskivirta20].
6.1 Hecke actions on coherent cohomology
Recall that
$K=K^p\mathcal {G}(\mathbb {Z}_p)$
is our level of moduli spaces. Let S be the finite set of primes
$\ell $
, where
$K_\ell $
is not hyperspecial. Consider the Hecke algebra
$$\begin{align*}\mathcal{H}^S=\bigotimes_{v\notin S}'\mathcal{H}_v,\end{align*}$$
the restricted tensor product of the spherical Hecke algebras
$\mathcal {H}_v=\mathbb {Z}_p[K_v\backslash G(\mathbb {Q}_v)/K_v]$
outside S. We assume that G is ramified over
$\mathbb {Q}_p$
, i.e.,
$p\in S$
, since otherwise all the following discussions are covered by [Reference Goldring and Koskivirta20].
Consider also the Hecke algebra
$\mathcal {H}_K$
. There is a natural morphism
$\mathcal {H}^S\rightarrow \mathcal {H}_K$
. Recall for any
${\mathcal {O}}_F$
-representation V of L, we have the automorphic vector bundle
$\mathcal {V}^{\mathrm {sub}}$
on the smooth toroidal compactification
$\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}$
as in subsection 5.3. In the following we describe the action of
$\mathcal {H}_K$
on the coherent cohomology groups
$H^i(\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}, \mathcal {V}^{\mathrm {sub}})$
, so that we get an induced action of
$\mathcal {H}^S$
. Since the Hecke algebra
$\mathcal {H}_K$
is generated by characteristic functions of
$KgK\in K\backslash G({\mathbb {A}}_f)/K$
with
$g\in G({\mathbb {A}}_f)$
, it suffices to describe the action of
$KgK$
on
$H^i(\mathsf {M}_{K,\Sigma }^{\mathrm {spl},\mathrm {tor}}, \mathcal {V}^{\mathrm {sub}})$
. Let
$K_g=K\cap gKg^{-1}$
. By [Reference Lan37] Proposition 2.4.17, we get the associated Hecke correspondence
where
$p_1$
is the natural projection,
$p_2$
is the composition of natural projection with
$g: \mathsf {M}_{K_g}^{\mathrm {spl}}\stackrel {\sim }{\rightarrow }\mathsf {M}_{g^{-1}K_gg}^{\mathrm {spl}}$
. For
$i=1,2$
, the induced
$\Sigma _g^i=p_i^\ast \Sigma $
are admissible finite rpcd for the level
$K_g$
. Let
$\Sigma _g$
be a common smooth refinement of
$\Sigma _g^1$
and
$\Sigma _g^2$
. Then by [Reference Lan37] Proposition 3.4.10, we get an extended Hecke correspondence
where
$q_i$
is the composition
$$\begin{align*}\mathsf{M}_{K_g,\Sigma_g}^{\mathrm{spl},\mathrm{tor}}\stackrel{r_i}{\longrightarrow} \mathsf{M}_{K_g,\Sigma_g^i}^{\mathrm{spl},\mathrm{tor}}\stackrel{\pi_i}{\longrightarrow} \mathsf{M}_{K,\Sigma}^{\mathrm{spl},\mathrm{tor}}.\end{align*}$$
The morphisms
$r_i$
satisfy
$R^jr_{i,\ast }{\mathcal {O}}_{\mathsf {M}_{K_g,\Sigma _g}^{\mathrm {spl},\mathrm {tor}}}=0$
for
$j>0$
and
$r_{i,\ast }{\mathcal {O}}_{\mathsf {M}_{K_g,\Sigma _g}^{\mathrm {spl},\mathrm {tor}}}={\mathcal {O}}_{\mathsf {M}_{K_g,\Sigma _g^i}^{\mathrm {spl},\mathrm {tor}}}$
by [Reference Lan37] Proposition 3.4.10 and [Reference Lan36] Proposition 7.5. By [Reference Lan37] Proposition 3.4.14, the schemes
$\mathsf {M}_{K_g,\Sigma _g^i}^{\mathrm {spl},\mathrm {tor}}$
are Cohen-Macaulay as
$\mathsf {M}_{K_g}^{\mathrm {spl}}$
is. Arguing as [Reference Goldring and Koskivirta20] 8.1.5, we get that the morphisms
$\pi _i$
are finite flat. Thus we get a trace map
$$\begin{align*}\textrm{tr}\pi_i: \pi_{i,\ast}{\mathcal{O}}_{\mathsf{M}_{K_g,\Sigma_g^i}^{\mathrm{spl},\mathrm{tor}}}\longrightarrow {\mathcal{O}}_{\mathsf{M}^{\mathrm{spl},\mathrm{tor}}_{K, \Sigma}},\end{align*}$$
which induces the associated Hecke operator: for each
$i\geq 0$
$$\begin{align*}T_g: H^i(\mathsf{M}_{K,\Sigma}^{\mathrm{spl},\mathrm{tor}}, \mathcal{V}^{\mathrm{sub}})\longrightarrow H^i(\mathsf{M}_{K,\Sigma}^{\mathrm{spl},\mathrm{tor}}, \mathcal{V}^{\mathrm{sub}}).\end{align*}$$
Let
$\varpi $
be a uniformizer of
${\mathcal {O}}_F$
. Recall the Levi subgroup L of
$P=P_\mu $
over
${\mathcal {O}}_F$
. For any
$i\geq 0, n\geq 1$
and
$(V,\eta )\in \mathrm {Rep}_{{\mathcal {O}}_F}L$
, consider the vector bundle
$\mathcal {V}_\eta ^{\mathrm {sub}}$
on
$\mathsf {M}_{K, \Sigma ,{\mathcal {O}}_F/\varpi ^n}^{\mathrm {spl},\mathrm {tor}}$
. we get an action
$$\begin{align*}\mathcal{H}^S\longrightarrow \operatorname{\mathrm{End}}\big(H^i(\mathsf{M}_{K, \Sigma,{\mathcal{O}}_F/\varpi^n}^{\mathrm{spl},\mathrm{tor}}, \mathcal{V}_\eta^{\mathrm{sub}})\big). \end{align*}$$
Let
$\mathcal {H}^{i,n}_\eta $
be its image.
6.2 Factorizations to
$H^0$
For any
$i\geq 0, n\geq 1$
and
$\eta \in X^\ast (T)_L^+$
, as in [Reference Goldring and Koskivirta20] we consider the following set
$$\begin{align*}F(i,n,\eta)=\{\eta'\in X^\ast(T)_L^+\,|\,\mathcal{H}^S\rightarrow \mathcal{H}^{i,n}_\eta\,\textrm{factors through}\,\mathcal{H}^S\rightarrow \mathcal{H}^{0,n}_{\eta'}\}.\end{align*}$$
With all the ingredients at hand, by the method of [Reference Goldring and Koskivirta20] we have the same consequences as Theorem 8.2.1 of loc. cit.
Theorem 6.1. For any
$(i,n,\eta )$
as above, we have
-
(1) There exists an arithmetic progression A such that
$\eta +a\eta _\omega \in F(i,n,\eta )$
for all
$a\in A\cap \mathbb {Z}_{\geq 1}$
. -
(2) Let
$\mathcal {C}$
be the cone defined in [Reference Goldring and Koskivirta20] 3.4.3. Then for all
$\nu \in \mathcal {C}$
and
$\eta _1\in F(i,n,\eta )$
, there exists
$m=m(\nu ,n)\in \mathbb {Z}_{\geq 1}$
such that for all
$j\in \mathbb {Z}_{\geq 1}$
, we have
$\eta _1+jm\nu \in F(i,n,\eta )$
. -
(3) For all
$\delta \in \mathbb {R}_{\geq 0}$
,
$F(i,n,\eta )$
contains a
$\delta $
-regular character in the sense of [Reference Goldring and Koskivirta20] Definition N.5.5.
The proof of the above theorem is by the same arguments as in [Reference Goldring and Koskivirta20] subsections 7.2, 7.3, 8.3 and 9.2. In particular, one plays with the machinery of Hasse-regular sequences based on our Corollaries 4.7, 5.5 and 5.7, Propositions 4.5 and 5.3, and one applies the associated flag space to increase the regularity. For the reader’s convenience, we recall that a Hasse regular sequence of length r with
$0\leq r\leq d=\dim \mathsf {M}^{\mathrm {spl}}_{K,F}$
on
$X:=\mathsf {M}^{\mathrm {spl},\mathrm {tor}}_{K,\Sigma , {\mathcal {O}}_F/\varpi ^n}$
(in the sense of [Reference Goldring and Koskivirta20] Definition 7.2.1) is given by a filtration of closed subschemes
$$\begin{align*}X=Z_0\supset Z_1\supset\cdots\supset Z_r \end{align*}$$
together with some integers
$a_j$
and global sections
$f_j\in H^0(Z_j, \omega _{\operatorname {\mathrm {Hdg}}}^{a_j})$
, such that each
$f_j$
is a lifting of a length Hasse invariant, and for each
$0\leq j\leq r-1$
, we have
$Z_{j+1}=V(f_j)$
. More precisely, on the reduced locus
$$\begin{align*}X_{\textrm{red}}=\coprod_{w\in {}^JW}X_w\supset Z_{j,\textrm{red}}=\coprod_{w\in {}^JW, \ell(w)\leq d-j}X_w.\end{align*}$$
By Proposition 4.4, there exists a large integer
$N_{d-j}$
and a length
$d-j$
Hasse invariant
$$\begin{align*}h_{d-j}\in H^0(Z_{j,\textrm{red}}, \omega_{\operatorname{\mathrm{Hdg}}}^{N_{d-j}})\end{align*}$$
such that its vanishing locus is
$Z_{j+1,\textrm {red}}=\coprod _{w\in {}^JW, \ell (w)\leq d-j-1}X_w$
. Then one requires
$$\begin{align*}f_j\in H^0(Z_j, \omega_{\operatorname{\mathrm{Hdg}}}^{a_j})\end{align*}$$
to be a lifting of certain power of
$h_{d-j}$
(which exists by [Reference Goldring and Koskivirta20] Theorem 5.1.1) for some integer
$a_j\geq N_{d-j}$
. From a regular Hasse sequence of length r, we get an exact sequence of sheaves over
$Z_{r-1}$
:
$$\begin{align*}0\longrightarrow \mathcal{V}_\eta^{\mathrm{sub}}\otimes\omega_{\operatorname{\mathrm{Hdg}}}^s\stackrel{\cdot f_{r-1}}{\longrightarrow} \mathcal{V}_\eta^{\mathrm{sub}}\otimes\omega_{\operatorname{\mathrm{Hdg}}}^{\otimes (a_{r-1}+s)} \longrightarrow \mathcal{V}_\eta^{\mathrm{sub}}\otimes\omega_{\operatorname{\mathrm{Hdg}}}^{\otimes (a_{r-1}+s)}|_{Z_r} \longrightarrow 0,\end{align*}$$
where
$\omega _{\operatorname {\mathrm {Hdg}}}$
is the Hodge line bundle and s is an integer. From here, one gets congruences between cohomology of different degrees using the vanishing result
$H^i(Z_r, \mathcal {V}_\eta ^{\mathrm {sub}}\otimes \omega _{\operatorname {\mathrm {Hdg}}}^m)=0$
for
$m\gg 0$
and
$i>0$
(cf. [Reference Goldring and Koskivirta20] Lemma 7.1.4). In particular, to study
$H^i(X, \mathcal {V}_\eta ^{\mathrm {sub}})$
, one performs a Hasse regular sequence of length i to finally reduce to
$H^0$
.
Remark 6.2.
-
(1) As mentioned above, in the unramified case Theorem 6.1 was proved by Goldring-Koskivirta in [Reference Goldring and Koskivirta20]; in this case part (1) also follows from the work of Boxer [Reference Boxer7].
-
(2) In the Hodge type case (which may be ramified), part (1) was proved by Pilloni-Stroh in [Reference Pilloni and Stroh52] (Théorème 3.5 and Remarque 3.9) for some quite different integral models (constructed by Scholze’s method). As they remarked there, the torsion classes for these integral models seem to be quite different from those associated to the unramified Kottwitz or Kisin models. Their torsion classes also seem to be rather different from those associated to the smooth splitting models here.
-
(3) By [Reference Goldring and Koskivirta20] Remark 8.2.4, parts (2) and (3) of Theorem 6.1 do not follow the methods of [Reference Boxer7] and [Reference Pilloni and Stroh52].
6.3 Galois representations
We can now deduce some consequences on Galois representations from Theorem 6.1 as in [Reference Goldring and Koskivirta20] section 10.
Let
$v\neq p$
be a finite unramified place of
$\mathbb {Q}$
for G. Let
$\operatorname {\mathrm {Frob}}_v$
be a geometric Frobenius at v and
$\mathcal {H}_v$
the unramified Hecke algebra at v. Then we have the Satake isomorphism (cf. [Reference Goldring and Koskivirta20] (10.2.1))
$$\begin{align*}\mathcal{H}_v[\sqrt{v}]\stackrel{\sim}{\rightarrow} R({}^LG_v)[\sqrt{v}],\end{align*}$$
where
$R({}^LG_v)$
is the algebra obtained by restricting character representations of
${}^LG_v$
to semisimple
${}^LG_v^\circ (\overline {\mathbb {Q}}_p)$
-conjugacy classes in
${}^LG_v\rtimes \operatorname {\mathrm {Frob}}_v$
. If
$\pi _v$
is an unramified irreducible smooth representation of
$G(\mathbb {Q}_v)$
, we get the corresponding semisimple
${}^LG_v^\circ (\overline {\mathbb {Q}}_p)$
-conjugacy class
$\mathrm {Sat}(\pi _v)$
, the Satake parameter of
$\pi _v$
.
Let
$$\begin{align*}r: {}^LG\rightarrow \operatorname{\mathrm{GL}}_m\end{align*}$$
be a representation of the Langlands dual group. For each place v as above, we get an induced representation
$r_v$
of
${}^LG_v$
. Let
$\pi $
be a C-algebraic cuspidal automorphic representation of G. If v is an unramified place of
$\pi $
, then we get
$$\begin{align*}r_v(\mathrm{Sat}(\pi_v))\in \operatorname{\mathrm{GL}}_m(\overline{\mathbb{Q}}_p).\end{align*}$$
Let
$Ram(\pi )$
be the set of ramified places of
$\pi $
. We say that
$(\pi ,r)$
satisfies
$LC_p$
, if there exists a continuous semisimple Galois representation
$$\begin{align*}\rho(\pi,r): \mathrm{Gal}(\overline{\mathbb{Q}}/\mathbb{Q})\rightarrow \operatorname{\mathrm{GL}}_m(\overline{\mathbb{Q}}_p)\end{align*}$$
such that for any
$v\notin Ram(\pi )\cup \{p\}$
, we have
$$\begin{align*}\rho(\pi,r)(\operatorname{\mathrm{Frob}}_v)=r_v(\mathrm{Sat}(\pi_v))\end{align*}$$
as
$\operatorname {\mathrm {GL}}_m(\overline {\mathbb {Q}}_p)$
-conjugacy classes.
For any
$j\geq 1$
, the function
${}^LG(\overline {\mathbb {Q}}_p)\rightarrow \mathbb {\overline {\mathbb {Q}}}_p,\, g\mapsto \textrm {tr}(r(g)^j)$
defines an element of
$R({}^LG_v)$
and thus an element
$T_v^{(j)}(r)\in \mathcal {H}_v[\sqrt {v}]$
. For any
$i\geq 0, n\geq 1, \eta \in X^\ast (T)_L^+$
, let
$$\begin{align*}T_v^{(j)}=T_v^{(j)}(r;i,n,\eta)\in \mathcal{H}^{i,n}_\eta\end{align*}$$
be its image in
$\mathcal {H}^{i,n}_\eta $
. In the following we fix
$\delta \in \mathbb {R}_{\geq 0}$
and
$r: {}^LG\rightarrow \operatorname {\mathrm {GL}}_m$
. Here is the version of [Reference Goldring and Koskivirta20] Theorems 10.4.1 and 10.5.1 in the ramified setting. The proof is identical to loc. cit. by applying Theorem 6.1 here. Part (1) also generalizes Theorem 1.1 of [Reference Reduzzi and Xiao56].
Theorem 6.3. Suppose that for any
$\delta $
-regular, C-algebraic cuspidal automorphic representation
$\pi '$
with
$\pi _{\infty }'$
discrete series, the pair
$(\pi ',r)$
satisfies
$LC_p$
.
-
(1) For any
$i\geq 0, n\geq 1, \eta \in X^\ast (T)_L^+$
, there exists a continuous Galois pseudo-representation such that
$$\begin{align*}\rho: \mathrm{Gal}(\overline{\mathbb{Q}}/\mathbb{Q})\longrightarrow \mathcal{H}^{i,n}_\eta, \end{align*}$$
$\rho (\operatorname {\mathrm {Frob}}_v^j)=T_v^{(j)}$
for all
$v\notin S$
.
-
(2) Let
$\pi $
be a C-algebraic cuspidal automorphic representation of G such that
$\pi _\infty $
is a (C-algebraic) non-degenerate limit of discrete series and
$\pi _p^{K_p}\neq 0$
. Then
$(\pi ,r)$
also satisfies
$LC_p$
.
Recall that
$K_p\subset G(\mathbb {Q}_p)$
is a very special parahoric subgroup, and irreducible smooth representations
$\pi _p$
of
$G(\mathbb {Q}_p)$
such that
$\pi ^{K_p}_p\neq 0$
can be classified by their spherical parameters, see [Reference Zhu71] section 6.
6.4 Examples
We discuss some concrete examples where the condition
$LC_p$
is essentially known. In these examples, the notation L is also used as certain number fields. Thus to avoid confusion, we denote
$\mathbf {L}\subset P_\mu $
for the Levi subgroup.
6.4.1 Unitary case
We use the notations of subsection 4.6.
For any regular C-algebraic cuspidal automorphic representation
$\pi $
of G, the associated Galois representation satisfying the condition
$LC_p$
is known to exist by the works of many people. We only mention [Reference Harris and Taylor22, Reference Shin62, Reference Chenevier and Harris11, Reference Clozel12].
Corollary 6.4. For any
$i\geq 0, n\geq 1, \eta \in X^\ast (T)_{\mathbf {L}}^+$
, there exists a continuous Galois pseudo-representation
$$\begin{align*}\rho: \mathrm{Gal}(\overline{L}/L)\longrightarrow \mathcal{H}^{i,n}_\eta, \end{align*}$$
such that
$\rho (\operatorname {\mathrm {Frob}}_v^j)=T_v^{(j)}$
for all
$v\notin S$
.
Here, when applying Theorem 6.3 we can replace
$\mathbb {Q}$
by the totally real field L, cf. [Reference Goldring and Koskivirta20] 10.6. One may also state and prove a similar version of [Reference Goldring and Koskivirta20] Theorem 10.5.3 for Galois representations associated to automorphic representations
$\pi $
with nondegenerate limit of discrete series
$\pi _{\infty }$
.
6.4.2 Hilbert-Siegel case
We use the notations of subsection 4.5.
For the group
$G=\operatorname {\mathrm {Res}}_{L|\mathbb {Q}}\operatorname {\mathrm {GSp}}_{2g}$
, any regular C-algebraic cuspidal automorphic representation
$\pi $
of G, the associated Galois representation satisfying the condition
$LC_p$
is known to exist for
$g\leq 2$
:
-
• for
$g=1$
, see [Reference Emerton, Reduzzi and Xiao16, Reference Reduzzi and Xiao56] and the references therein for the related classical works, -
• for
$g=2$
this has been intensively studied, see [Reference Taylor64, Reference Laumon39, Reference Weissauer67, Reference Sorensen63] for example, -
• for general g, see [Reference Kret and Shin31, Reference Xu69] for some recent progress.
Corollary 6.5. Assume the condition
$LC_p$
holds. For any
$i\geq 0, n\geq 1, \eta \in X^\ast (T)_{\mathbf {L}}^+$
, there exists a continuous Galois pseudo-representation
$$\begin{align*}\rho: \mathrm{Gal}(\overline{L}/L)\longrightarrow \mathcal{H}^{i,n}_\eta, \end{align*}$$
such that
$\rho (\operatorname {\mathrm {Frob}}_v^j)=T_v^{(j)}$
for all
$v\notin S$
.
Here, as above, when applying Theorem 6.3 we can replace
$\mathbb {Q}$
by the totally real field L. One may also state and prove a version for Galois representations associated to automorphic representations
$\pi $
with nondegenerate limit of discrete series
$\pi _{\infty }$
.
Appendix A Local models and EKOR stratifications in ramified PEL-type case
In this appendix, we first review the related local model diagrams for integral models of PEL-type Shimura varieties with general parahoric level at p, following [Reference Pappas and Rapoport49]. Then we briefly explain how to extend the construction of [Reference Shen, Yu and Zhang59] to this setting (the groups of [Reference Shen, Yu and Zhang59] are supposed to be tamely ramified at p as those in [Reference Kisin and Pappas28], but the construction there only needs local model diagrams as the input).
A.1 Integral models of PEL-type Shimura varieties
We keep the notations and assumptions of section 2. Let G be the connected reductive group defined by the rational PEL datum and
${\mathscr {L}}$
a multichain of
${\mathcal {O}}_B$
-lattices (see Definition A.1). By [Reference Pappas and Rapoport49], there are three integral models
$\mathscr {A}^{\operatorname {\mathrm {naive}}}, \mathscr {A}$
, and
$\mathscr {A}^{\mathrm {spl}}$
of the PEL moduli space over E (with respect to the multichain
${\mathscr {L}}$
). The models
$\mathscr {A}^{\operatorname {\mathrm {naive}}}, \mathscr {A}$
are defined over
${\mathcal {O}}_E$
and
$\mathscr {A}^{\mathrm {spl}}$
is defined over
${\mathcal {O}}_F$
. We first recall the definition of PEL datum with parahoric level structure following [Reference Rapoport55], see also the appendix of [Reference Shen, Yu and Zhang59] or [Reference Hartwig23] section 2.
A.1.1 Parahoric data at p
To simplify the notation, we will write
$(B,*, V, \psi =\left \langle \cdot , \cdot \right \rangle , {\mathcal {O}}_B, \Lambda )$
for the base change of such data in section 2 to
$\mathbb {Q}_p$
. So we have
$$\begin{align*}B \simeq \prod_{i=1}^r \operatorname{\mathrm{M}}_{m_i}(R_i), \quad {\mathcal{O}}_B \simeq \prod_{i=1}^r \operatorname{\mathrm{M}}_{m_i}({\mathcal{O}}_{R_i}). \end{align*}$$
By Morita equivalence, we can decompose the B-module V (resp. any
${\mathcal {O}}_B$
-lattice
$\Lambda $
in V) as
$$\begin{align*}V =\bigoplus_{i=1}^r V_i^{m_i} \quad (\textrm{ resp. } \Lambda \simeq \bigoplus_{i=1}^r \Lambda_i^{m_i}),\end{align*}$$
where each factor
$V_i$
is a free
$R_i$
-module (resp.
$\Lambda _i$
is an
$\mathcal {O}_{B_i}$
-lattice in
$V_i$
). Write
$2d_i = \operatorname {\mathrm {rank}}_{F_i} V_i$
.
Definition A.1.
-
(1) A chain of
${\mathcal {O}}_B$
-lattices in V is a set of totally ordered
${\mathcal {O}}_B$
-lattices
${\mathscr {L}}$
such that for every element
$x \in B^\times $
which normalizes
${\mathcal {O}}_B$
, one has
$$\begin{align*}\Lambda \in {\mathscr{L}} \implies x \Lambda \in {\mathscr{L}}. \end{align*}$$
-
(2) A set
${\mathscr {L}}$
of
${\mathcal {O}}_B$
-lattices in V is said to be a multichain of
${\mathcal {O}}_B$
-lattices if there exists a chain of
$\mathcal {O}_{B_i}$
-lattices
${\mathscr {L}}_i$
in
$V_i$
for each
$i=1,\dots , m$
such that for any member
$\Lambda \in {\mathscr {L}}$
one has
$\Lambda _i \in {\mathscr {L}}_i$
for all
$i=1,\dots ,m$
. -
(3) A multichain of
${\mathcal {O}}_B$
-lattices
${\mathscr {L}}$
is called self-dual if for every member
$\Lambda \in {\mathscr {L}}$
, its dual lattice
$\Lambda ^\vee $
also belongs to
${\mathscr {L}}$
, where
$$\begin{align*}\Lambda^\vee := \{x \in V \mid \psi(x,\Lambda) \subset \mathbb{Z}_p\}.\end{align*}$$
For a multichain
${\mathscr {L}}$
of
${\mathcal {O}}_B$
-lattices, we write
$$\begin{align*}{\mathcal{G}} = {\mathcal{G}}_{{\mathscr{L}}}\end{align*}$$
for the group scheme over
$\mathbb {Z}_p$
defined by the stabilizer of the multichain
${\mathscr {L}}$
as in [Reference Rapoport55, §6]. By [Reference Haines and Richarz21, Corollary 4.8], for a reductive group of the form
$G = \operatorname {\mathrm {Res}}_{F|{\mathbb {Q}}_p} G'$
, every parahoric group scheme of G is of the form
$\operatorname {\mathrm {Res}}_{{\mathcal {O}}_F|{\mathbb {Z}}_p} {\mathcal {G}}'$
for a unique parahoric group scheme
${\mathcal {G}}'$
of
$G'$
. If we assume that
$G'$
unramified, the stabilizer group scheme
${\mathcal {G}} = {\mathcal {G}}_{\mathscr {L}}$
associated to
${\mathscr {L}}$
is always connected. So
${\mathcal {G}}$
is a parahoric group scheme of G and (since the prime to p level
$K^p$
is fixed) we write
$K=\mathcal {G}(\mathbb {Z}_p)$
.
A.1.2 Integral models
Now let
$\operatorname {\mathrm {AV}}$
be the category of abelian varieties with
${\mathcal {O}}_B$
-actions, where morphisms are prime to p isogenies.
Definition A.2. Let
${\mathscr {L}}$
be a multichain of
${\mathcal {O}}_B$
-lattices in V. A
${\mathscr {L}}$
-set of abelian varieties over a
$\mathbb {Z}_{p}$
-scheme S is a functor
$$\begin{align*}{\mathscr{L}} \to \operatorname{\mathrm{AV}},\quad \Lambda \mapsto A_\Lambda,\end{align*}$$
satisfying the following.
-
(1) For each inclusion
$\Lambda \subset \Lambda '$
in
${\mathscr {L}}$
, a quasi-isogeny
$A_\Lambda \to A_{\Lambda '}$
. -
(2) For any element
$a \in B^\times \cap {\mathcal {O}}_B$
which normalizes
${\mathcal {O}}_B$
and any member
$\Lambda \in {\mathscr {L}}$
, there exists an isomorphism
$\theta _{a,\Lambda }: A_\Lambda ^a \to A_{a\Lambda }$
such that the following diagram commutes
Let
${\mathscr {L}}$
be a self-dual multichain of
${\mathcal {O}}_B$
-lattices in V, and fix a sufficiently small open compact subgroup
$K^p \subset G(\mathbb {A}_f^p)$
. Recall that E is the local reflex field. There is a naive integral model
$\mathscr {A}^{\operatorname {\mathrm {naive}}}_{\mathscr {L}}$
over
${\mathcal {O}}_E$
, which is a moduli scheme classifying the objects
$(A_{\mathscr {L}}, \overline {\lambda },\overline {\eta })/S$
for each scheme
$S/{\mathcal {O}}_E$
, where
-
•
$A_{\mathscr {L}} = (A_\Lambda )_{\Lambda \in {\mathscr {L}}}$
is a
${\mathscr {L}}$
-set of abelian schemes over S in
$\operatorname {\mathrm {AV}}$
; -
•
$\overline {\lambda } = \mathbb {Q}^\times \cdot \lambda $
is a
$\mathbb {Q}$
-homogeneous principal polarization on
$A_{\mathscr {L}}$
; -
•
$\overline {\eta }$
is a
$\pi _1(S,\overline {s})$
-invariant
$K^p$
-orbit of isomorphism
$\eta : V \otimes \mathbb {A}_f^p \to T^p(A_{\overline {s}})$
which preserves the pairings up to a scalar in
$(\mathbb {A}_f^p)^\times $
. Here
$T^p(A_{\overline {s}})$
is the prime to p Tate module of
$A_{\overline {s}}$
and for simplicity we assume that S is connected.
For the exact meaning of the above terms, we refer to [Reference Pappas and Rapoport49, Reference Rapoport55, Reference Lan37] and appendix of [Reference Shen, Yu and Zhang59].
In general the naive model
$\mathscr {A}^{\operatorname {\mathrm {naive}}}_{\mathscr {L}}$
is not flat over
${\mathcal {O}}_E$
, cf. [Reference Pappas45]. In order to define a good integral model, Pappas and Rapoport introduced an alternative integral model of
$\mathscr {A}^{\operatorname {\mathrm {naive}}}_{\mathscr {L}} \otimes _{{\mathcal {O}}_E} F$
in [Reference Pappas and Rapoport49], where F is a large enough extension of E (which contains the Galois closure of E over
$\mathbb {Q}_p$
). We briefly recall their construction. To this end, we find it convenient to use Lan’s formulation of splitting structures ([Reference Lan37]).
Definition A.3 ([Reference Lan37, Definition 2.1.12]).
Suppose that S is a scheme over
${\mathcal {O}}_F$
. A
${\mathscr {L}}$
-set of polarized
${\mathcal {O}}_B \otimes {\mathcal {O}}_S$
-modules is a triple
$(\underline {{\mathcal {H}}}, \underline {\mathscr {F}},\underline {\iota })$
, where:
-
(1)
$\underline {{\mathcal {H}}}: \Lambda \mapsto {\mathcal {H}}_\Lambda $
and
$\underline {\mathscr {F}}: \Lambda \mapsto \mathscr {F}_\Lambda $
are functors from the category
${\mathscr {L}}$
to the category of
${\mathcal {O}}_B\otimes {\mathcal {O}}_S$
-modules. -
(2) For each
$\Lambda \in {\mathscr {L}}$
, both
$\mathscr {F}_{\Lambda }$
and
${\mathcal {H}}_{\Lambda }/\mathscr {F}_{\Lambda }$
are finite locally free
${\mathcal {O}}_S$
-modules, such that
${\mathcal {H}}_{\Lambda }/\mathscr {F}_{\Lambda }$
satisfies the determinant condition. -
(3) For other conditions, we refer to Lan’s paper [Reference Lan37].
Definition A.4 ([Reference Lan37, Definition 2.3.3]; see also [Reference Pappas and Rapoport49] Definition 14.1).
Suppose that S is a scheme over
${\mathcal {O}}_F$
, and that
$(\underline {\mathcal {H}},\underline {\mathscr {F}},\underline {\iota })$
is a
${\mathscr {L}}$
-set of polarized
${\mathcal {O}}_B \otimes \mathcal {O}_S$
-modules. A splitting structure for
$(\underline {\mathcal {H}},\underline {\mathscr {F}},\underline {\iota })$
is a collection
$$\begin{align*}\underline{{\mathscr{F}}_{\bullet}}=(\mathscr{F}_{i,j}^l, \iota_{i,j}^l)_{1\leq i\leq r, 1\leq j \leq f_i, 0 \leq l \leq e_i},\end{align*}$$
where each
$\mathscr {F}_{i,j}^l: \Lambda \to \mathscr {F}_{\Lambda ,i,j}^l$
is a functor from the category
${\mathscr {L}}$
to the category of
${\mathcal {O}}_B \otimes \mathcal {O}_S$
-modules, and each
$\iota _{i,j}^l: \mathscr {F}_{\Lambda , i,j}^l \to {\mathcal {H}}_{\Lambda ,i,j}$
is an injective morphism satisfying the following conditions (identify
$\mathscr {F}_{i,j}^l$
with its image under
$\iota $
):
-
(1) For each
$\Lambda \in {\mathscr {L}}$
, we require both
$\mathscr {F}_{\Lambda ,i,j}^l$
and
${\mathcal {H}}_{\Lambda ,i,j} / \mathscr {F}_{\Lambda ,i,j}^l$
to be finite locally free
$\mathcal {O}_S$
-modules. -
(2) For each
$\Lambda \in {\mathscr {L}}$
and
$1 \leq i \leq r, 1\leq j \leq f_i$
, we have a filtration as
$$\begin{align*}0 = \mathscr{F}_{\Lambda,i,j}^0 \subset \mathscr{F}_{\Lambda,i,j}^1 \subset \cdots \subset \mathscr{F}_{\Lambda,i,j}^{e_i} = \mathscr{F}_{\Lambda,i,j}\end{align*}$$
${\mathcal {O}}_B \otimes \mathcal {O}_S$
-submodule of
${\mathcal {H}}_{\Lambda ,i,j}$
. For each integer
$0 < l \leq e_i$
, the quotient
$\mathscr {F}_{\Lambda ,i,j}^l / \mathscr {F}_{\Lambda ,i,j}^{l-1}$
is a locally free
$\mathcal {O}_S$
-module of rank
$d_{i,j}^l$
, annihilated by
$b \otimes 1 - 1 \otimes \sigma _{i,j}^l(b)$
for all
$b \in {\mathcal {O}}_{F_i}$
.
-
(3) For each
$\Lambda \in {\mathscr {L}}$
and
$i \in \mathscr {I}$
, there are periodicity isomorphisms, cf. [Reference Lan37] p. 2475 for more details. -
(4) For each
$\Lambda \in {\mathscr {L}}$
and tuples
$(i,j,l)$
, let
$(\mathscr {F}_{\Lambda ,i,j}^l)^\perp $
denote the orthogonal complement of
$\mathscr {F}_{\Lambda ,i,j}^l$
in
${\mathcal {H}}_{\Lambda ^\vee ,i,j}$
with respect to the perfect pairing
${\mathcal {H}}_{\Lambda ,i,j} \times {\mathcal {H}}_{\Lambda ^\vee ,i,j} \to {\mathcal {O}}_S$
. Then
$$\begin{align*}\prod_{0\leq k < l} (b \otimes 1 - 1 \otimes \sigma_{i,j}^{k}(b)) ((\mathscr{F}_{\Lambda,i,j}^{l})^\perp) \subset \mathscr{F}_{\Lambda^\vee,i,j}^l.\end{align*}$$
Let
$\mathscr {A}^{\mathrm {spl}}_{\mathscr {L}}$
be the moduli scheme over
${\mathcal {O}}_F$
classifying the objects
$(A_{\mathscr {L}},\overline {\lambda },\overline {\eta }, \underline {\mathscr {F}_{\bullet }})$
for each scheme
$S/{\mathcal {O}}_F$
, where
$(A_{\mathscr {L}},\overline {\lambda },\overline {\eta })$
is an object in
$\mathscr {A}^{\operatorname {\mathrm {naive}}}_{\mathscr {L}}(S)$
and
$\underline {\mathscr {F}_{\bullet }}$
is a splitting structure for the
${\mathscr {L}}$
-set of polarized
${\mathcal {O}}_B \otimes {\mathcal {O}}_S$
-modules associated with
$(A_{\mathscr {L}},\overline {\lambda },\overline {\eta })$
. This is the splitting model associated to the PEL datum. With the notation of [Reference Lan37], we have
$$\begin{align*}\mathscr{A}^{\mathrm{spl}}_{\mathscr{L}}=\mathrm{Spl}^+_{(\underline{\mathcal{H}},\underline{{\mathscr{F}}},\underline{\iota})/\mathscr{A}^{\operatorname{\mathrm{naive}}}_{\mathscr{L}}\otimes {\mathcal{O}}_F}. \end{align*}$$
In the following, we will simply write
${\mathscr {A}}^{\mathrm {spl}}$
and
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
for the schemes
$\mathscr {A}^{\mathrm {spl}}_{\mathscr {L}}$
and
$\mathscr {A}^{\operatorname {\mathrm {naive}}}_{\mathscr {L}}$
, respectively. Let
$\mathscr {A}$
be the scheme-theoretic image of the natural morphism
$$\begin{align*}\mathscr{A}^{\mathrm{spl}} \to {\mathscr{A}}^{\operatorname{\mathrm{naive}}} \otimes_{{\mathcal{O}}_E} {\mathcal{O}}_F \to \mathscr{A}^{\operatorname{\mathrm{naive}}}.\end{align*}$$
The natural morphism
$$\begin{align*}{\mathscr{A}}^{\mathrm{spl}} \rightarrow {\mathscr{A}}\end{align*}$$
is projective by [Reference Lan37] Proposition 2.3.7. Both
${\mathscr {A}}^{\mathrm {spl}}$
and
$\mathscr {A}$
admit better geometric properties than the naive integral model
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
.
A.2 Local models
The local structure of integral models of Shimura varieties is controlled by the associated local models. There is a naive local model
$\mathbb {M}^{\operatorname {\mathrm {naive}}}$
associated to the moduli scheme
$\mathscr {A}^{\operatorname {\mathrm {naive}}}$
. Recall that
${\mathbb {M}}^{\operatorname {\mathrm {naive}}} := {\mathbb {M}}^{\operatorname {\mathrm {naive}}}(\mathcal {G},\mu )$
is the moduli scheme over
${\mathcal {O}}_E$
given by the following definition.
Definition A.5 [Reference Rapoport55].
A point of
${\mathbb {M}}^{\operatorname {\mathrm {naive}}}$
with values in an
${\mathcal {O}}_E$
-scheme S is given by the following data.
-
(1) A functor from the category
${\mathscr {L}}$
to the category of
${\mathcal {O}}_B \otimes {\mathcal {O}}_S$
-modules on S:
$$\begin{align*}\Lambda \to t_\Lambda, \quad\Lambda \in {\mathscr{L}}.\end{align*}$$
-
(2) A morphism of functors
$$\begin{align*}\varphi_\Lambda: \Lambda \otimes_{{\mathbb{Z}}_p} {\mathcal{O}}_S \to t_\Lambda.\end{align*}$$
We require the following conditions to be satisfied:
-
(1)
$t_\Lambda $
is a finite locally free
${\mathcal {O}}_S$
-module. The
${\mathcal {O}}_B$
-action on
$t_\Lambda $
satisfies the determinant condition
$$\begin{align*}\det_{{\mathcal{O}}_S} (a; t_\Lambda) = \det_F (a; W), \quad a \in {\mathcal{O}}_B.\end{align*}$$
-
(2) The morphisms
$\varphi _\Lambda $
are surjective. -
(3) The composition of the following maps is zero for each
$\Lambda $
:
$$\begin{align*}t_\Lambda^* \to (\Lambda \otimes {\mathcal{O}}_S)^* \cong \hat{\Lambda} \otimes {\mathcal{O}}_S \to t_{\hat{\Lambda}}.\end{align*}$$
The naive local model
$\mathbb {M}^{\operatorname {\mathrm {naive}}}$
is usually not flat in the ramified case, cf. [Reference Pappas45]. We define the splitting local model
$$\begin{align*}\mathbb{M}^{\mathrm{spl}}=\mathbb{M}^{\mathrm{spl}}(\mathcal{G},\mu)\end{align*}$$
as the moduli scheme over
${\mathcal {O}}_F$
classifying the splitting structures over
$\mathbb {M}^{\operatorname {\mathrm {naive}}} \otimes _{{\mathcal {O}}_E} {\mathcal {O}}_F$
. The splitting model
$\mathbb {M}^{\mathrm {spl}}$
admits good properties. Recall that we assume that there is no type (AR) local factors.
Proposition A.6. The splitting local model
$\mathbb {M}^{\mathrm {spl}}$
is flat over
${\mathcal {O}}_F$
.
Proof. This is a direct generalization of [Reference Pappas and Rapoport49, Theorems 5.3 and 9.4]. For the reader’s convenience, we briefly recall their proofs. Without loss of generality, we may assume that
$r=1$
and we slightly change the notation: let
$G=G_1$
be the associated reductive group over
$\mathbb {Q}_p$
. So we have
$$\begin{align*}G = \operatorname{\mathrm{Res}}_{{F_1}|{\mathbb{Q}}_p} G'\end{align*}$$
for an unramified group
$G'$
over a local field
${F_1}|{\mathbb {Q}}_p$
. Since
$F|{\mathbb {Q}}_p$
contains the Galois closure of
${F_1}$
, we have
$$\begin{align*}G_F = \prod_{\tau: {F_1} \to F} G^{\prime}_\tau, \text{ where } G^{\prime}_\tau := G' \otimes_{{F_1},\tau} F.\end{align*}$$
The projection of
$$\begin{align*}\mu: {\mathbb{G}}_{m,F} \to G_F = \prod_{\tau: {F_1} \to F} G^{\prime}_\tau\end{align*}$$
to each factor
$G^{\prime }_\tau $
gives a cocharacter
$\mu _\tau : {\mathbb {G}}_{m,F} \to G^{\prime }_\tau $
. Moreover, for each
$\tau : {F_1}\to F$
, one can associate an
${\mathcal {O}}_F$
-multichain by
$$\begin{align*}{\mathscr{L}}_\tau := \{\Lambda_\tau = \Lambda \otimes_{{\mathcal{O}}_{F_1}} {\mathcal{O}}_F \mid \Lambda \in {\mathscr{L}}\}.\end{align*}$$
Such a multichain determines a parahoric subgroup of
$G^{\prime }_\tau $
. This gives a local model (over
${\mathcal {O}}_F$
)
$$\begin{align*}{\mathbb{M}}^{{\mathrm{loc}}}_\tau := {\mathbb{M}}^{{\mathrm{loc}}}(G^{\prime}_\tau, \mu_\tau)_{{\mathscr{L}}_\tau}.\end{align*}$$
By our assumption,
$G'$
is unramified over F, so
${\mathbb {M}}^{{\mathrm {loc}}}$
is the same as the naive local model. This means that for each
${\mathcal {O}}_F$
-scheme S,
${\mathbb {M}}^{{\mathrm {loc}}}(S)$
classifies the set of multichains
$\{{\mathscr {F}}_{\Lambda ,\tau }\}_{\Lambda \in {\mathscr {L}}} \subset {\mathscr {L}}_\tau $
which is compatible with transition maps, and each
${\mathscr {F}}_{\Lambda ,\tau }$
is Zariski locally on S an
${\mathcal {O}}_S$
-direct summand of
$\Lambda _\tau $
of rank
$d_{\tau }$
.
Given the splitting local model
${\mathbb {M}}^{\mathrm {spl}}={\mathbb {M}}^{\mathrm {spl}}(\mathcal {G},\mu )$
over
${\mathcal {O}}_F$
, one has the following diagram (which is a modified version of the diagrams (5.10) and (9.13) in [Reference Pappas and Rapoport49])
For each
${\mathcal {O}}_F$
-scheme S,
$\widetilde {{\mathbb {M}}}^{\mathrm {spl}}(S)$
classifies
$$\begin{align*}({\mathscr{F}}_{\Lambda,j}^l, {\varphi_{\Lambda,j}^l: \Upsilon_{\Lambda,j}^{l} \simeq \Lambda_{j}^l}\otimes_{{\mathcal{O}}_F} {\mathcal{O}}_S)_{\Lambda \in {\mathscr{L}}},\end{align*}$$
where
$({\mathscr {F}}_{\Lambda ,j}^l)_{\Lambda \in {\mathscr {L}},j}^l \in {\mathbb {M}}^{\mathrm {spl}}(S)$
,
$\varphi _j^l$
is an isomorphism from the
${\mathcal {O}}_S$
-module
$$\begin{align*}\Upsilon_{\Lambda,j}^l := \operatorname{\mathrm{Ker}}((\pi \otimes 1 - 1 \otimes \sigma_j^l(\pi)) |_{ \Lambda_{j,S}^l / {\mathscr{F}}_{\Lambda,j}^{l-1}})\end{align*}$$
to the
${\mathcal {O}}_S$
-module
$\Lambda _{j}^l\otimes _{{\mathcal {O}}_F} {\mathcal {O}}_S$
with
$$\begin{align*}\Lambda_j^l := \Lambda \otimes_{{\mathcal{O}}_F,\sigma_j^l} {\mathcal{O}}_F.\end{align*}$$
Such a trivialization exists Zariski locally on S by [Reference Pappas and Rapoport49, Propositions 5.2, 9.2] (this reference only covers the case of type (C) and (AL); the case of type (AU) can be proved by the same argument). The map
$\pi _1$
is the natural forgetful morphism, and
$\pi _2$
sends
$({\mathscr {F}}_{\Lambda ,j}^l, {\varphi _{\Lambda ,j}^l})$
to
$\varphi _{\Lambda ,j}^l({\mathscr {F}}_{\Lambda ,j}^{l} / {\mathscr {F}}_{\Lambda ,j}^{l-1}) \in {\mathbb {M}}^{{\mathrm {loc}}}_{\sigma _{j}^l}$
.
Let
${\mathcal {G}}_j^l$
be the subgroup of
$\prod _{\Lambda \in {\mathscr {L}}} \operatorname {\mathrm {Aut}}(\Lambda _{j}^l)$
compatible with the transition maps of
${\mathscr {L}}$
, and
${\mathcal {G}}^{\mathrm {spl}} := \prod _{j,l}{\mathcal {G}}_{j}^l$
. Then the action
$$\begin{align*}g_j^l \cdot ({\mathscr{F}}_{\Lambda,j}^l, {\varphi_{\Lambda,j}^l}) = ({\mathscr{F}}_{\Lambda,j}^l, {g_j^l \varphi_{\Lambda,j}^l})\end{align*}$$
makes
$\pi _1$
a
$\prod _{j,l\geq 2}{\mathcal {G}}_{j}^l$
-torsor. The other action
$$\begin{align*}g_j^l \cdot ({\mathscr{F}}_{\Lambda,j}^l, {\varphi_{\Lambda,j}^l}) = ((\varphi_{\Lambda,j}^l)^{-1} g_j^l \varphi_{\Lambda,j}^l({\mathscr{F}}_{\Lambda,j}^l), {g_j^l \varphi_{\Lambda,j}^l})\end{align*}$$
makes
$\pi _2$
a
$\prod _{j,l\geq 2}{\mathcal {G}}_{j}^l$
-torsor. Now the existence of such a diagram of torsors for a smooth group scheme and the flatness of unramified local models implies the flatness of
${\mathbb {M}}^{\mathrm {spl}}$
.
Proposition A.7.
-
(1) Let
$\mathbb {M}^{\mathrm {loc}}=\mathbb {M}^{\mathrm {loc}}(\mathcal {G},\mu )$
be the scheme-theoretic image of the natural forgetful morphism
$\mathbb {M}^{\mathrm {spl}} \to \mathbb {M}^{\operatorname {\mathrm {naive}}}$
. Then
$\mathbb {M}^{\mathrm {loc}}$
coincides with the local model
${\mathbb {M}}$
defined in [Reference Levin40] with respect to the triple
$(G,\mu ,K_{\mathscr {L}})$
. -
(2) We have the following naive local model diagram:
-
(3) We have a local model diagram:
-
(4) The pullback of the natural morphism
${\mathbb {M}}^{\mathrm {spl}} \to {\mathbb {M}}^{\operatorname {\mathrm {naive}}}$
gives the splitting local model diagram with respect to the group
${\mathcal {G}}$
over
${\mathcal {O}}_F$
([Reference Pappas and Rapoport49, §15])
Proof. We only need to show that
${\mathbb {M}}$
coincides with
${\mathbb {M}}^{\mathrm {loc}}$
, as the other statements are contained in [Reference Pappas and Rapoport49]. The image
${\mathbb {M}}^{\mathrm {loc}}$
is flat by the flatness of
${\mathbb {M}}^{\mathrm {spl}}$
. As the generic fiber of
${\mathbb {M}}$
agrees with
${\mathbb {M}}^{\operatorname {\mathrm {naive}}}$
,
${\mathbb {M}}$
is the flat closure of the generic fiber of
${\mathbb {M}}^{\operatorname {\mathrm {naive}}}$
, which agrees with
${\mathbb {M}}^{\mathrm {{\mathrm {loc}}}}$
by definition.
In order to study the geometry of
${\mathscr {A}}_0^{\mathrm {spl}}$
, we would like to show that there is a local model diagram of splitting models with respect to the splitting group
${\mathcal {G}}^{\mathrm {spl}}$
in the next paragraph. This means that there is a
${\mathcal {G}}^{\mathrm {spl}}$
-torsor
$\widetilde {{\mathscr {A}}^{\mathrm {spl}}}$
over
${\mathscr {A}}^{\mathrm {spl}}$
, and a
${\mathcal {G}}^{\mathrm {spl}}$
-equivariant morphism
$\widetilde {{\mathscr {A}}^{\mathrm {spl}}} \to {\mathbb {M}}^{{\mathrm {loc}}}({\mathcal {G}}^{\mathrm {spl}}, \mu )$
.
For every scheme S over
${\mathcal {O}}_F$
and each
$\Lambda \in {\mathscr {L}}$
, we define the
${\mathcal {O}}_S$
-module
$\Upsilon _{\Lambda ,i,j}^l$
as
$$\begin{align*}\Upsilon_{\Lambda,i,j}^l := \operatorname{\mathrm{Ker}}( (\pi_i \otimes 1 - 1 \otimes \sigma_{i,j}^l(\pi_i)) |_{\mathcal{H}_{i,j}/{\mathscr{F}}_{i,j}^l}).\end{align*}$$
Consider also the
${\mathcal {O}}_F$
-lattice
$\Lambda _{i,j}^l := \Lambda _i \otimes _{{\mathcal {O}}_{F_i}, \sigma _{i,j}^l} {\mathcal {O}}_F$
. Then Zariski locally there exists an isomorphism
$$\begin{align*}\Upsilon_{\Lambda,i,j}^l \simeq \Lambda_{i,j}^l\otimes_{{\mathcal{O}}_F}{\mathcal{O}}_S,\end{align*}$$
see the proof of Proposition A.6. For every
$\Lambda \in {\mathscr {L}}$
, we can define an
${\mathcal {O}}_S$
-module
${\mathcal {M}}_\Lambda $
as
$$\begin{align*}{\mathcal{M}}_\Lambda :=\bigoplus_i{\mathcal{M}}_{\Lambda,i}^{m_i},\quad {\mathcal{M}}_{\Lambda ,i}:= \bigoplus_{j,l} \Upsilon_{\Lambda,i,j}^l,\end{align*}$$
so it is locally isomorphic to the
${\mathcal {O}}_F$
-lattice
$$\begin{align*}\Lambda^{\mathrm{spl}} :=\bigoplus_i \Lambda^{\mathrm{spl}, m_i}_i,\quad \Lambda^{\mathrm{spl}}_i:= \bigoplus_{j,l} \Lambda_{i,j}^l.\end{align*}$$
Consider the group
$$\begin{align*}{\mathcal{G}}^{\mathrm{spl}}_\Lambda := \operatorname{\mathrm{Aut}}(\Lambda^{\mathrm{spl}}) \subset \prod_{i,j,l} {\mathcal{G}}_{\Lambda,i,j}^l.\end{align*}$$
We simply define the splitting group
${\mathcal {G}}^{\mathrm {spl}}$
as
$$\begin{align*}{\mathcal{G}}^{\mathrm{spl}} =\bigcap_{\Lambda \in {\mathscr{L}}} {\mathcal{G}}_{\Lambda}^{\mathrm{spl}}.\end{align*}$$
For each
$i,j,l$
, let
${\mathcal {G}}_{i,j}^l$
be the group scheme over
${\mathcal {O}}_F$
defined by the automorphism of the multichain
$(\Lambda _{i,j}^l)_{\Lambda \in {\mathscr {L}}}$
. Then it admits a decomposition as
${\mathcal {G}}^{\mathrm {spl}}=\prod _{i,j,l}\mathcal {G}^l_{i,j}$
. Now we define
$$\begin{align*}{\mathbb{M}}^{{\mathrm{loc}}}({\mathcal{G}}^{\mathrm{spl}},\mu):=\prod_{i,j,l}{\mathbb{M}}^{\mathrm{loc}}(\mathcal{G}_{i,j}^l,\mu_{i,j}^l),\end{align*}$$
where on the right hand side each
${\mathbb {M}}^{\mathrm {loc}}(\mathcal {G}_{i,j}^l,\mu _{i,j}^l)$
is the local model attached to the pair
$(\mathcal {G}_{i,j}^l,\mu _{i,j}^l)$
. Note that if we consider the natural
${\mathcal {G}}^{\mathrm {spl}}$
-action on
${\mathbb {M}}^{{\mathrm {loc}}}({\mathcal {G}}^{\mathrm {spl}},\mu )$
, as in the proof of Proposition A.6 we get the following diagram of schemes over
${\mathcal {O}}_F$
for splitting local models (modified version of the diagrams (5.10) and (9.13) of [Reference Pappas and Rapoport49]):
where
$\pi _1$
is the
$\prod _{i,j,l\geq 2}\mathcal {G}^l_{i,j}$
-torsor, and q is a
${\mathcal {G}}^{\mathrm {spl}}$
-equivariant morphism. Note that
$q = \pi _2$
, but here we only consider the group action on
$\widetilde {{\mathbb {M}}}^{\mathrm {spl}}({\mathcal {G}},\mu )$
given by
$\pi _1$
. One can see that such action is compatible with the natural
$\prod _{i,j,l\geq 2}\mathcal {G}^l_{i,j}$
-action on
${\mathbb {M}}^{{\mathrm {loc}}}({\mathcal {G}}^{\mathrm {spl}}, \mu )$
. This motivates the following local model diagram for splitting integral models.
Proposition A.8. We have the following local model diagram for splitting models:
where for every
${\mathcal {O}}_F$
-scheme S,
${\widetilde {\mathscr {A}^{\mathrm {spl}}}}(S)$
classifies isomorphism classes of
$$\begin{align*}(\underline{A}_{{\mathscr{L}}}, \underline{{\mathscr{F}}}_{{\mathscr{L}}}, ({\tau}_{\Lambda, i, j}^l:\Upsilon_{\Lambda,i,j}^l \simeq \Lambda_{i, j}^l\otimes_{{\mathcal{O}}_F} {\mathcal{O}}_S)_{\Lambda \in {\mathscr{L}}} ),\end{align*}$$
with
$(\underline {A}_{{\mathscr {L}}}, \underline {{\mathscr {F}}}_{{\mathscr {L}}}) \in {\mathscr {A}}^{\mathrm {spl}}(S)$
, and
${\tau }_{{\mathscr {L}}} := \{{\tau }_{\Lambda ,i,j}^l\}$
can be viewed as a trivialization of the multi-chain
$({\mathcal {M}}_\Lambda )_{\Lambda \in {\mathscr {L}}}$
. The morphism
$\pi $
is the natural forgetful morphism, which is a
${\mathcal {G}}^{\mathrm {spl}}$
-torsor. The morphism q is the natural
${\mathcal {G}}^{\mathrm {spl}}$
-equivariant smooth morphism given by
$$\begin{align*}(\underline{A}_{{\mathscr{L}}}, \underline{{\mathscr{F}}}_{{\mathscr{L}}}, \{{\tau}_{\Lambda, i, j}^l\}) \mapsto \{{\tau}_{\Lambda,i,j}^l({\mathscr{F}}_{\Lambda,i,j}^l / {\mathscr{F}}_{\Lambda,i,j}^{l-1})\}_{\Lambda \in {\mathscr{L}}}.\end{align*}$$
Proof. Combining the diagram in Proposition A.7(4) and the diagram in the proof of Proposition A.6, one has the following diagram
Let
$\widetilde {\widetilde {{\mathscr {A}}^{\mathrm {spl}}}}$
be the product of
$q'$
and
$\pi _1$
, then we have a new diagram
where
$\pi "$
is a
${\mathcal {G}}_{{\mathcal {O}}_F} \times \prod _{i,j, l \geq 2} {\mathcal {G}}_{i,j}^l$
-torsor, and we can check that the same action of
$\pi "$
makes
$q"'$
a
${\mathcal {G}}_{{\mathcal {O}}_F} \times \prod _{i,j, l \geq 2} {\mathcal {G}}_{i,j}^l$
-equivariant smooth morphism. Note that we always have
$\Lambda _i^1 \subset \Lambda $
, so the restriction of the
${\mathcal {G}}$
-action on
$\Lambda $
induces a natural morphism
$$\begin{align*}{\mathcal{G}}_{{\mathcal{O}}_F} = \operatorname{\mathrm{Aut}}(\Lambda \otimes {\mathcal{O}}_F) \to \operatorname{\mathrm{Aut}}(\bigoplus_{i}\Lambda_i^1) = {\mathcal{G}}^1. \end{align*}$$
So we can push the
${\mathcal {G}}$
-torsor
$\pi "$
along the natural morphism
${\mathcal {G}}_{{\mathcal {O}}_F} \to {\mathcal {G}}^1$
to get
$\widetilde {\mathscr {A}^{\mathrm {spl}}}$
, a
$\mathcal {G}^{\mathrm {spl}}=\prod _{i,j,l}\mathcal {G}_{i,j}^l$
-torsor. Moreover, the
${\mathcal {G}}_{{\mathcal {O}}_F} \times \prod _{i,j, l \geq 2} {\mathcal {G}}_{i,j}^l$
-action on
${\mathbb {M}}^{{\mathrm {loc}}}({\mathcal {G}}^{\mathrm {spl}}, \mu )$
factors through
$\mathcal {G}^{\mathrm {spl}}$
, therefore the morphism
$q"'$
factors through
$\widetilde {\mathscr {A}^{\mathrm {spl}}}$
and induces a
$\mathcal {G}^{\mathrm {spl}}$
-equivariant morphism
$q: \widetilde {\mathscr {A}^{\mathrm {spl}}}\rightarrow {\mathbb {M}}^{{\mathrm {loc}}}({\mathcal {G}}^{\mathrm {spl}}, \mu )$
. This gives the diagram
claimed in the proposition.
A.3 EKOR stratification
Recall that we write
$\kappa $
for the residue field of
${\mathcal {O}}_E$
, and
$k = \overline {\kappa }$
for the algebraic closure of
$\kappa $
. We will construct the EKOR stratification of
$$\begin{align*}\mathscr{A}_0 := \mathscr{A} \otimes k\end{align*}$$
from its local model diagram, following the idea of [Reference Shen, Yu and Zhang59].
Fix the triple
$(G,\mu , K)$
with associated parahoric group scheme
${\mathcal {G}} $
. We have the attached local model
$\mathbb {M}^{\mathrm {loc}}=\mathbb {M}^{{\mathrm {loc}}}(\mathcal {G},\mu )$
equipped with a left action of
${\mathcal {G}}$
. Let
${\mathcal {G}}_0 = {\mathcal {G}} \otimes k$
and
$M^{\mathrm {loc}} = \mathbb {M}^{\mathrm {loc}} \otimes k$
. For
$K=\mathcal {G}(\mathbb {Z}_p)$
, let
$\operatorname {\mathrm {Adm}}(\mu )_K$
be the
$\mu $
-admissible set as in [Reference Shen, Yu and Zhang59] 1.2. By [Reference Pappas and Rapoport49, Reference Levin40, Reference Haines and Richarz21], we have
Corollary A.9. There is a set-theoretically disjoint union of locally closed subsets
$$\begin{align*}M^{\mathrm{loc}} = \coprod_{w \in \operatorname{\mathrm{Adm}}(\mu)_K} M^w.\end{align*}$$
Moreover, we have
-
(1) The closure
$\overline {M^{w}} = \coprod _{v \leq w} M^v$
; -
(2) Each
$M^w$
consists of a single
${\mathcal {G}}_0$
-orbit, and the stabilizer of each closed point is smooth.
The decomposition of
$M^{\mathrm {loc}}$
induces the KR (Kottwitz-Rapoport) stratification
$$\begin{align*}{\mathscr{A}}_0=\coprod_{w\in \operatorname{\mathrm{Adm}}(\mu)_K}{\mathscr{A}}_0^w,\end{align*}$$
where for each
$w \in \operatorname {\mathrm {Adm}}(\mu )_K$
,
${\mathscr {A}}_0^w$
is the fiber of the morphism of algebraic stacks over k induced by the local model diagram (cf. Proposition A.7 (3))
$$\begin{align*}{\mathscr{A}}_0 \to [{\mathcal{G}}_0 \backslash M^{\mathrm{loc}}].\end{align*}$$
Each
${\mathscr {A}}_0^w$
is a locally closed smooth subvariety of
${\mathscr {A}}_0$
, and we have
$$\begin{align*}\overline{{\mathscr{A}}_0^w} = \coprod_{w' \leq w} {\mathscr{A}}_0^{w'}.\end{align*}$$
Consider the local model diagram
where
$\pi $
is a
${\mathcal {G}}_0$
-torsor and q is
${\mathcal {G}}_0$
-equivariant. For each
$w \in \operatorname {\mathrm {Adm}}(\mu )_K$
, let
$J_w$
be the set defined in 1.3.6 of [Reference Shen, Yu and Zhang59], and
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
the reductive quotient of
${\mathcal {G}}_0$
. By the same method of [Reference Shen, Yu and Zhang59, §3], there is a
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
-zip of type
$J_w$
over
${\mathscr {A}}_0^w$
, written as
$$\begin{align*}({\mathbb{I}}^w, {\mathbb{I}}^w_+, {\mathbb{I}}^w_-, \iota).\end{align*}$$
The tuple
$({\mathbb {I}}^w, {\mathbb {I}}^w_+, {\mathbb {I}}^w_-, \iota )$
then induces a morphism of stacks
$$\begin{align*}\zeta_w: {\mathscr{A}}_0^w \to {{\mathcal{G}}_0^{\operatorname{\mathrm{rdt}}}}\text{-}\mathrm{Zip}^{J_w}.\end{align*}$$
The proof of [Reference Shen, Yu and Zhang59, Theorem 3.4.11] gives
Corollary A.10. The morphism
$\zeta _w$
is smooth.
Let
$W=W_{{\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}}$
be the Weyl group of
${\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}$
. Then the underlying topological space of
${{\mathcal {G}}_0^{\operatorname {\mathrm {rdt}}}}\text {-}\mathrm {Zip}^{J_w}$
is given by the partially ordered set
${}^{J_w} W$
. For each
$x \in {}^{J_w} W$
, define
${\mathscr {A}}_0^x := \zeta _w^{-1}(x)$
. Then
${\mathscr {A}}_0^x$
is a locally closed subvariety of
${\mathscr {A}}_0^w$
. Letting
$w\in \operatorname {\mathrm {Adm}}(\mu )_K$
vary, we get
$$\begin{align*}{\mathscr{A}}_0 = \coprod_{w \in \operatorname{\mathrm{Adm}}(\mu)_K, x \in {}^{J_w} W} {\mathscr{A}}_0^x.\end{align*}$$
We will call such decomposition the EKOR stratification of
${\mathscr {A}}_0$
.
The index set of EKOR strata is in fact given by the partially ordered set
$({}^K \operatorname {\mathrm {Adm}}(\mu ), \leq _{K,\sigma })$
of [Reference Shen, Yu and Zhang59] 1.2. There is a natural surjection
$$\begin{align*}\pi: {}^K\operatorname{\mathrm{Adm}}(\mu) \to \operatorname{\mathrm{Adm}}(\mu)_K,\end{align*}$$
such that for every
$w \in \operatorname {\mathrm {Adm}}(\mu )_K$
, the fiber
$\pi ^{-1}(w)$
is bijective to the partially ordered set
${}^{J_w} W$
by [Reference Shen, Yu and Zhang59] 1.3.6.
Example A.11 (EKOR strata of Hilbert modular varieties).
Consider
$B = L$
, a totally real field over
$\mathbb {Q}$
and
$V = L^2$
, then G is a subgroup of
$ \operatorname {\mathrm {Res}}_{L|\mathbb {Q}} \operatorname {\mathrm {GL}}_2$
. In this case, the canonical model
${\mathscr {A}}$
(with maximal parahoric level at p) was constructed in [Reference Deligne and Pappas13] and coincides with
${\mathscr {A}}^{\operatorname {\mathrm {naive}}}$
. Let
$x = (A, \lambda , \iota , \alpha ) \in {\mathscr {A}}_0(k)$
and
${\mathcal {H}}$
,
$\omega $
the corresponding k-vector spaces as above. For each
$i,j$
,
${\mathcal {H}}_{i,j} \simeq k[\varepsilon _i]^2$
and
$\omega _{i,j} \subset {\mathcal {H}}_{i,j}$
is a
$k[\varepsilon _i]$
-submodule with k-dimension
$e_i$
, so there is an integer
$a_{i,j}$
such that
$$\begin{align*}\omega_{i,j} \simeq (\varepsilon_i^{a_{i,j}}) \oplus (\varepsilon_i^{e_i - a_{i,j}}), \text{ for a unique integer } 0 \leq a_{i,j} \leq \lfloor\frac{e_i}{2}\rfloor.\end{align*}$$
For each tuple
$a = (a_{i,j})$
such that
$0 \leq a_{i,j} \leq \lfloor \frac {e_i}{2}\rfloor $
, let
$$\begin{align*}{\mathscr{A}}_0^a := \{x \in {\mathscr{A}}_0 \mid \omega_{x,i,j} \simeq (\varepsilon_i^{a_{i,j}}) \oplus (\varepsilon_i^{e_i - a_{i,j}}) \text{ for all } i, j\}.\end{align*}$$
Then
$$\begin{align*}{\mathscr{A}}_0 = \coprod_a {\mathscr{A}}_0^a\end{align*}$$
is the KR stratification of
${\mathscr {A}}_0$
. The stratum
${\mathscr {A}}_0^a$
is locally closed subvariety of
${\mathscr {A}}_0$
of dimension
$\sum _{i,j} (e_i - 2 a_{i,j})$
with closure relation given by
$$\begin{align*}a \leq a' \text{ if and only if } a_{i,j} \geq a^{\prime}_{i,j} \text{ for all } i,j.\end{align*}$$
Now consider the tuple
$a=(a_{i,j})$
such that
$x \in {\mathscr {A}}_0^a(k)$
, then
$a_{i,j}$
is the maximal integer such that
$$\begin{align*}\omega_{i,j} \subset \varepsilon_i^{a_{i,j}} {\mathcal{H}}_{i,j}.\end{align*}$$
If we write
$M_{i,j} = {\mathcal {H}}_{i,j} / \varepsilon _i {\mathcal {H}}_{i,j}$
, the Verschiebung map
${\mathcal {H}}_{i,j+1} \to {\mathcal {H}}_{i,j}$
induces a morphism
$$\begin{align*}V_{i,j}: M_{i,j+1} \to \varepsilon_i^{a_{i,j}} {\mathcal{H}}_{i,j} / \varepsilon_i^{a_{i,j}+1} {\mathcal{H}}_{i,j} \simeq M_{i,j}.\end{align*}$$
Conversely, we first assume that
$a_{i,j} < e_i/2$
, the Frobenius map
${\mathcal {H}}_{i,j} \to {\mathcal {H}}_{i,j+1}$
induces a morphism
$$\begin{align*}F_{i,j}: M_{i,j} \simeq \varepsilon_i^{a_{i,j}} {\mathcal{H}}_{i,j} / \varepsilon_i^{a_{i,j}+1} {\mathcal{H}}_{i,j} \to \varepsilon_i^{2a_{i,j}} {\mathcal{H}}_{i,j+1} / \varepsilon_i^{2a_{i,j}+1} {\mathcal{H}}_{i,j+1} \simeq M_{i,j+1}.\end{align*}$$
For
$a_{i,j} = e_i/2$
, let
$F_{i,j} = 0$
, then we have the tuple
$$\begin{align*}(M := \bigoplus_{i,j} M_{i,j}, F:= \bigoplus_{i,j} F_{i,j}, V:= \bigoplus_{i,j} V_{i,j})\end{align*}$$
such that M is a k-vector space with semilinear morphisms
$F,V$
satisfying the equation
$$\begin{align*}\operatorname{\mathrm{Im}}(F) = \operatorname{\mathrm{Ker}}(V),\quad \operatorname{\mathrm{Ker}}(F) = \operatorname{\mathrm{Im}}(V).\end{align*}$$
The type of the F-zip
$(M,\operatorname {\mathrm {Ker}}(V), \operatorname {\mathrm {Ker}}(F),\varphi _{\bullet })$
is determined by the dimension of
$\operatorname {\mathrm {Ker}}(V)$
, which is equal to the number of the indices
$(i,j)$
such that
$a_{i,j} \neq e_i/2$
. More explicitly, consider the function
$$\begin{align*}\delta(u) = \begin{cases} 0, & u = 0; \\ 1, & u \neq 0. \end{cases}\end{align*}$$
For each tuple
$a=(a_{i,j})$
corresponding to a KR stratum
${\mathscr {A}}_0^a$
, set
$$\begin{align*}t_a := \sum_{i,j} \delta(e_i - 2 a_{i,j}).\end{align*}$$
There are
$t_a+1$
EKOR strata contained in
${\mathscr {A}}_0^a$
. The EKOR type of a point
$x \in {\mathscr {A}}_0^a(k)$
is given by an integer
$0 \leq t_x \leq t_a$
, and the EKOR stratum containing x has dimension
$\dim ({\mathscr {A}}_0^a) - t_x$
.
A.4 Global construction of EKOR stratification
We will show that the closure relation of the EKOR strata is given by the partially ordered set
$({}^K\operatorname {\mathrm {Adm}}(\mu ), \leq _{K,\sigma })$
. All results and detailed definitions come from [Reference Shen, Yu and Zhang59, §4] with exactly the same proofs (note that thanks to the recent works [Reference Anschütz, Gleason, Lourenço and Richarz1, Reference Gleason and Lourenço18] the perfection of the geometric special fiber
$M^{{\mathrm {loc}}}$
of the local model here can be embedded into the associated Witt vector affine flag variety, similar to the tamely ramified case used in [Reference Shen, Yu and Zhang59]). So we omit all proofs in this subsection and refer to loc. cit. for detailed arguments.
Keep the notations as in the last subsection. Let
$C({\mathcal {G}},\mu )$
be the index set of central leaves in [Reference Shen, Yu and Zhang59, §1]. There is a prestack
$\operatorname {\mathrm {Sht}}_{\mu ,K}^{{\mathrm {loc}}}$
over
$k = \overline {{\mathbb {F}}}_p$
classifying
${\mathcal {G}}$
-Shtukas of type
$\mu $
, whose k-points are given by
$$\begin{align*}\operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}}(k) = C({\mathcal{G}}, \mu).\end{align*}$$
There is a prestack
$\operatorname {\mathrm {Sht}}_{\mu ,K}^{{\mathrm {loc}}(\infty ,1)}$
over k, parameterizing the so-called
$(\infty ,1)$
-restricted local Shtukas. For sufficiently large integer m, there is an algebraic stack
$\operatorname {\mathrm {Sht}}_{\mu ,K}^{{\mathrm {loc}}(m,1)}$
over k, parameterizing the so-called
$(m,1)$
-restricted local Shtukas, such that (see [Reference Shen, Yu and Zhang59, Lemma 4.2.4])
$$\begin{align*}|\operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}(\infty,1)}| \simeq |\operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}(m,1)}| \simeq {}^K\operatorname{\mathrm{Adm}}(\mu).\end{align*}$$
We also have natural maps (which are perfectly smooth by [Reference Shen, Yu and Zhang59, Proposition 4.2.5])
$$\begin{align*}\operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}} \to \operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}(\infty,1)} \to \operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}(m,1)} \to [{\mathcal{G}}_0 \backslash M^{{\mathrm{loc}}}].\end{align*}$$
Consider the perfection
${\mathscr {A}}_0^{\operatorname {\mathrm {pf}}} = \varprojlim _\sigma {\mathscr {A}}_0$
of
${\mathscr {A}}_0$
. Then the same proof of [Reference Shen, Yu and Zhang59, Proposition 4.4.1] shows that there exists a morphism of prestacks
$$\begin{align*}{\mathscr{A}}_0^{\operatorname{\mathrm{pf}}} \to \operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}}.\end{align*}$$
Composing this morphism with the natural morphism
$\operatorname {\mathrm {Sht}}_{\mu ,K}^{{\mathrm {loc}}} \to \operatorname {\mathrm {Sht}}_{\mu ,K}^{{\mathrm {loc}}(m,1)}$
, we get a morphism of stacks
$$\begin{align*}v_K: {\mathscr{A}}_0^{\operatorname{\mathrm{pf}}} \to \operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}(m,1)}.\end{align*}$$
Recall that the local model diagram gives the morphism of stacks
$$\begin{align*}\lambda_K: {\mathscr{A}}_0^{\operatorname{\mathrm{pf}}} \to [{\mathcal{G}}_0 \backslash M^{{\mathrm{loc}}}],\end{align*}$$
which is perfectly smooth. The same proof as [Reference Shen, Yu and Zhang59, Theorem 4.4.3] (there is a small gap in the last step of the proof concerning the involved diagram, which is inherited from the corresponding place of the work of Xiao-Zhu; but a small modification without the commutativity of that diagram will make the argument still work, cf. [Reference Shen and Zhang60].) shows
Theorem A.12. The following diagram commutes:
Moreover,
$v_K$
is perfectly smooth.
Consider the morphism of stacks
$$\begin{align*}v_K: {\mathscr{A}}_0^{\operatorname{\mathrm{pf}}} \to \operatorname{\mathrm{Sht}}_{\mu,K}^{{\mathrm{loc}}(m,1)}.\end{align*}$$
We know that
$|\operatorname {\mathrm {Sht}}_{\mu ,K}^{{\mathrm {loc}}(m,1)}| \simeq {}^K\operatorname {\mathrm {Adm}}(\mu )$
, the fibers of
$v_K$
are then the EKOR strata of
${\mathscr {A}}_0^{\operatorname {\mathrm {pf}}}$
. As we have the identification of underlying topological spaces
$$\begin{align*}|{\mathscr{A}}_0^{\operatorname{\mathrm{pf}}}| = |{\mathscr{A}}_{0}|.\end{align*}$$
The perfect smoothness of
$v_K$
shows that
Corollary A.13. For any
$x \in {}^K\operatorname {\mathrm {Adm}}(\mu )$
, the Zariski closure of the EKOR stratum
${\mathscr {A}}_{0}^x$
is given by
$$\begin{align*}\overline{{\mathscr{A}}_{0}^x} = \coprod_{x' \leq_{K,\sigma} x} {\mathscr{A}}_{0}^{x'}.\end{align*}$$
A.5 Nonemptiness of EKOR strata
We recall the proof of nonemptiness of EKOR strata following [Reference He and Zhou26]. Our situation is slightly different from loc. cit. as the groups there are required to be tamely ramified at p. Nevertheless their method equally applies to our case.
Let
${\tau }_\mu $
be the minimal element in
$\operatorname {\mathrm {Adm}}(\mu )$
with respect to the Bruhat order. Let
$\breve {I}$
be a fixed Iwahori subgroup of
$\breve {G}:=G(\breve {{\mathbb {Q}}}_p)$
. For simplicity, we may assume that the lattice
${\mathscr {L}}$
is determined by a finite index set
$J = \{0,\dots ,m\}$
.
Let
$B(G)$
be the set of
$\sigma $
-conjugacy classes in
$\breve {G}$
. Recall that the Kottwitz set (the index set of the Newton stratification of
${\mathscr {A}}_0$
) is
$$\begin{align*}B(G,\mu) = \{[b] \in B(G) \mid \kappa([b]) = \mu^\#, \nu([b]) \leq \overline{\mu}\}.\end{align*}$$
There is a unique basic element
$[b_0]\in B(G,\mu )$
. By [Reference Kisin, Madapusi Pera and Shin29, Theorem 1], the basic locus of
${\mathscr {A}}_0$
is non-empty. Let
$x = (A_j, \lambda _j, \alpha )_{j\in J} \in {\mathscr {A}}(k)$
be a point in the basic locus. Let
$D_j$
be the Dieudonné module of
$A_j[p^\infty ]$
and N be the common rational Dieudonné module. Then
$D_j$
form a lattice chain inside N. The Frobenius gives
$\delta \in \breve {G} $
such that
$[\delta ] = [b_0] \in B(G,\mu )$
.
For any
$w \in W_K \backslash \widetilde {W} / W_K$
and
$b \in \breve {G}$
, The affine Deligne-Lusztig variety is defined as
$$\begin{align*}X_{K,w}(b) = \{g \in \breve{G} / \breve{K} \mid g^{-1} b \sigma(g) \in \breve{K} w \breve{K}\}.\end{align*}$$
If
$\breve {K} = \breve {I}$
, we simply write the corresponding affine Deligne-Lusztig variety as
$X_w(b)$
. For an element
$w\in \widetilde {W}$
, let
$\dot {w}$
be a representative of it in
$\breve {G}$
. The following lemma will be used in the proof of nonemptiness of EKOR strata.
Lemma A.14.
-
(1)
$\dot {\tau }_\mu $
is central. -
(2)
$X_{{\tau }_\mu }(\delta )$
is non-empty.
Proof. Recall that we have the isomorphism
$$\begin{align*}\widetilde{W} \simeq W_a \rtimes \pi_1(G)_{\Gamma_0}, \end{align*}$$
where
$W_a$
is the affine Weyl group of G. Under this isomorphism, the minimal element
${\tau }_\mu $
corresponds to
$(\operatorname {\mathrm {id}}, \mu ^\#) \in W_a \rtimes \pi _1(G)_{\Gamma _0}$
. By the proof of [Reference Pappas and Rapoport50, Appendix, Lemma 14], such element lifts to the torus
$\breve {T} \subset \breve {G}$
. So
${\tau }_\mu $
is central in
$\widetilde {W}$
and its lift is also central in
$\breve {G}$
.
We have
$$\begin{align*}X_{{\tau}_\mu}(\delta) \neq \emptyset \iff \breve{I} {\tau}_\mu \breve{I} \cap [\delta] \neq \emptyset\end{align*}$$
by definition. As
${\tau }_\mu $
is a
$\sigma $
-straight element in
$\widetilde {W}$
,
$\breve {I} {\tau }_\mu \breve {I}$
lies in a single
$\sigma $
-conjugacy class of
$\breve {G}$
by [Reference He and Rapoport25, Theorem 5.1.(a)]. Moreover, such conjugacy class is given by
$[\delta ]$
. This shows the nonemptiness of
$X_{{\tau }_\mu }(\delta )$
.
Proposition A.15. We have
${\mathscr {A}}_{0}^x \neq \emptyset $
for all
$x \in {}^K\operatorname {\mathrm {Adm}}(\mu )$
Proof. By Lemma A.14 (2), there is an element
$g \in X_{{\tau }_\mu }(\delta )$
. Then
$g^{-1} \delta \sigma (g) \in \breve {I} \dot {\tau }_\mu \breve {I}$
. Lemma A.14 (1) shows that
$\delta \sigma (g) \in g \dot {\tau }_\mu \breve {I}$
. This gives
$$\begin{align*}p g D_j \subset \delta \sigma(g) D_j = \dot{\tau}_\mu g D_j \subset g D_j,\end{align*}$$
which essentially shows that
$$\begin{align*}\operatorname{\mathrm{Frob}} (g D_j) = \delta \sigma(g) D_j \subset g D_j.\end{align*}$$
Thus
$g D_j$
corresponds to a p-divisible group which is isogenous to
$A_j[p^\infty ]$
, so we get an abelian variety
$g A_j$
. The polarization
$\lambda _j$
and
${\mathcal {O}}_B$
-action extends naturally to
$g A_j$
. The prime to p level structure
$\alpha $
also extends to
$g A_j$
; we thus obtain a triple
$(g A_j, g \lambda _j, \alpha )$
. This triple gives a k-point
$g x \in {\mathscr {A}}_I(k)$
. By construction,
$g x$
must live in the minimal EKOR stratum. Then by closure relation, we get the nonemptiness of EKOR strata.
Acknowledgments
We thank Sian Nie for some helpful discussions. We would like to thank the referee for careful reading and detailed comments, which helped to improve the paper.
Competing interest
The authors have no competing interests to declare.
Financial support
The first author was partially supported by the National Key R
$\&$
D Program of China 2020YFA0712600, the CAS Project for Young Scientists in Basic Research, Grant No. YSBR-033, and the NSFC grant No. 12288201.
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