1. Introduction
In recent years, there has been a growing interest in the study of rationality properties of characters of finite groups and their relationship to global-local properties, which relate the character theory of a finite group to p-local subgroups for a prime p. In this article, we are concerned with the p-rationality of height-zero characters of finite groups.
Let B be a p-block of a finite group G and let
${\mathrm {Irr}}(B)$
denote the set of ordinary irreducible characters of B. The ( p-)height of a character
$\chi \in {\mathrm {Irr}}(B)$
is given by
$$\begin{align*}{\mathbf{ht}(\chi):=\nu(\chi(1))-\min_{\psi\in {\mathrm{Irr}}(B)}\{\nu(\psi(1))\}},\end{align*}$$
where
$\nu :=\nu _p$
is the usual p-adic valuation function. We say that
$\chi $
is height-zero if
$\mathbf {ht}(\chi )=0$
. In other words, the height-zero characters of B are those characters in B whose degrees have the minimal possible p-part.
To measure how p-rational (or p-irrational) a character
$\chi $
is, one considers the p-part of the conductor of its values
$\{\chi (g): g\in G\}$
. Recall that every character value is a certain sum of roots of unity. Such a sum is called a cyclotomic integer. The conductor
$c(\mathcal {S})$
of a collection
$\mathcal {S}$
of cyclotomic integers is the smallest positive integer n such that
$\mathcal {S}\subseteq {\mathbb Q}(\exp (2\pi i/n))$
. For
$\chi \in {\mathrm {Irr}}(G)$
, we write
$c(\chi ):= c(\{\chi (g):g\in G\})$
and call this the conductor of
$\chi $
. The so-called p-rationality level of
$\chi $
is defined as
$$\begin{align*}{\mathbf{lev}}(\chi):=\nu(c(\chi)). \end{align*}$$
We put forward the following, which proposes that the p-rationality level of a height-zero character can be captured inside a local subgroup, namely, the defect normalizer.
Conjecture A. Let p be a prime, G a finite group, and
$\chi $
be a height-zero character in a block B of G with
${\mathbf {lev}}(\chi )\geq 2$
. Suppose that D is a defect group of B. Then,
$$\begin{align*}{\mathbf{lev}}(\chi)={\mathbf{lev}}(\chi_{{\mathbf{N}}_G(D)}).\end{align*}$$
Remark 1.1. For
$g\in G$
, let
${\mathbf {lev}}(\chi (g)):=\nu _p(c(\chi (g)))$
– the p-rationality level of
$\chi (g)$
. It is easy to see that
$$\begin{align*}{\mathbf{lev}}(\chi)=\max_{g\in G}\{{\mathbf{lev}}(\chi(g))\},\end{align*}$$
so there exists
$g\in G$
such that
${\mathbf {lev}}(\chi (g))={\mathbf {lev}}(\chi )$
. That is, there exists an element in the group that captures the p-rationality of
$\chi $
. Conjecture A simply claims that such an element can be found in
${\mathbf {N}}_G(D)$
.
Height-zero characters are well known for their nice behavior with respect to the global-local principle. Among the first observations of this was in Brauer’s height zero conjecture, recently resolved in [Reference Malle, Navarro, Schaeffer Fry and Tiep23], which states that all irreducible characters in a block B have height zero if and only if the defect groups of B are abelian. Another example is the celebrated Alperin–McKay conjecture. (See, e.g., [Reference Navarro25, Conjecture 9.5]. See also [Reference Ruhstorfer30], where the conjecture was recently proven for
$p=2$
.) The Alperin–McKay conjecture asserts that if b is the block of
${\mathbf {N}}_G(D)$
corresponding to B in Brauer’s first main correspondence, then there exists a bijection between the height-zero characters in B and those in b. Conjecture A offers another global-local phenomenon for height-zero characters. In fact, we observe in §7 a relationship between Conjecture A and the well-known Alperin–McKay–Navarro (AMN) conjecture, which refines the Alperin–McKay conjecture to further include the action of Galois automorphisms.
Conjecture A is inspired by Navarro–Tiep’s conjecture [Reference Navarro and Tiep28, Conjecture C]. In what follows,
${\mathrm {Irr}}(G)$
denotes the set of irreducible characters of G and
${\mathrm {Irr}}_{p'}(G)$
the subset of
${\mathrm {Irr}}(G)$
consisting of characters of degree not divisible by p. Furthermore, for any positive integer n, we use
${\mathbb Q}_n$
to denote the n-th cyclotomic field
${\mathbb Q}_n:={\mathbb Q}(\exp (2\pi i/n))$
.
Conjecture B ([Reference Navarro and Tiep28, Conjecture C], Conjecture C).
Let p be a prime, G a finite group,
$P\in {\mathrm {Syl}}_p(G)$
, and
$\chi \in {\mathrm {Irr}}_{p'}(G)$
with
${\mathbf {lev}}(\chi )\geq 1$
. Then,
$$\begin{align*}{\mathbb Q}_{p^{{\mathbf{lev}}(\chi)}}={\mathbb Q}_p(\chi_P).\end{align*}$$
Conjecture B implies that if a
$p'$
-degree character
$\chi $
has p-rationality level at least 2, then its level remains unchanged when restricted to a Sylow p-subgroup:
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{P})$
. (However, note that for
${\mathbf {lev}}(\chi )=1$
, this is false - see, Example 7.3.) Recall that a
$p'$
-degree character is a height-zero character lying in a block of maximal defect, which means that the defect groups are the Sylow p-subgroups of G. In such a case, Conjecture A only asserts that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(P)})$
. In particular, Conjecture B implies Conjecture A in the case of
$p'$
-degree characters. However, it is important to note that for height-zero characters in general,
${\mathbf {lev}}(\chi )$
does not always equal
${\mathbf {lev}}(\chi _{D})$
, see the examples in §7.3. We refer the reader to [Reference Isaacs and Navarro20], [Reference Navarro and Tiep28] for further discussion on Conjecture B.
What evidence do we have for Conjecture A? Our first main result confirms the cyclic-defect case.
Theorem C. Let p be a prime and G a finite group. Let
$B\in \mathrm {\mathrm {Bl}}(G)$
be a p-block of G with cyclic defect group D and
$\chi \in {\mathrm {Irr}}(B)$
. Then,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
.
Remark 1.2. The assumption on
${\mathbf {lev}}(\chi )$
in Conjecture A is essential. There are many examples with
${\mathbf {lev}}(\chi )=1$
but
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})=0$
, see again §7.3. Theorem C, however, shows that this cannot occur when a defect group D is cyclic.
The proof of Theorem C is based on Dade’s cyclic-defect theory [Reference Dade6], [Reference Dade7]. When the defect groups of B are cyclic, the set
${\mathrm {Irr}}(B)$
is naturally partitioned into two types: exceptional characters and non-exceptional characters, see §3.2. While the characters of the latter type are always p-rational, we show that the p-rationality level of an exceptional character aligns with that of its associated (linear) character of the defect group D. Another key step is to show that if an element
$g\in G$
captures the p-rationality of a character
$\chi $
in a block with cyclic defect groups, then its p-part
$g_p$
generates a defect group of the block. This is done in §3.
Our next result solves Conjecture B for prime-degree characters, and therefore confirms Conjecture A for characters whose degree is a prime different from p.
Theorem D. Let p be a prime and G a finite group. Let
$\chi \in {\mathrm {Irr}}(G)$
be of prime degree not equal to p with
${\mathbf {lev}}(\chi )\geq 2$
. Let
$P\in {\mathrm {Syl}}_p(G)$
. Then,
${\mathbb Q}_{p^{{\mathbf {lev}}(\chi )}}={\mathbb Q}_p(\chi _P)$
. In particular,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(P)})={\mathbf {lev}}(\chi _{P})$
.
The proof of Theorem D is divided into two fundamentally different cases, depending on whether the character in question is primitive or imprimitive. The imprimitive case builds on ideas from the recent solution of Conjecture B for p-solvable groups [Reference Isaacs and Navarro20], as detailed in §4. In contrast, the primitive case is reduced to analyzing the values of prime-degree characters of quasisimple groups, which is addressed in §§5 and 6.
§5.2 provides an additional evidence supporting Conjecture A for certain almost quasisimple groups. Finally, §7 discusses some consequences and examples related to Conjecture A, along with its connection to the well-known AMN conjecture.
To conclude this introduction, we mention recent work of Navarro, Ruhstorfer, Tiep, and Vallejo [Reference Navarro, Ruhstorfer, Tiep and Vallejo27] concerning the determination of fields of values of p-height zero characters of finite groups. They proposed that an abelian number field F with conductor
$p^am$
, where p does not divide m, arises as the field of values of a p-height zero irreducible character of a finite group if and only if
$[{\mathbb Q}_{p^a}:({\mathbb Q}_{p^a}\cap {\mathbb Q}_mF)]$
is not divisible by p. They reduced this conjecture to a question about blocks of quasisimple groups and ultimately verified it in the case
$p=2$
.
2. Galois automorphisms and p-rationality level
Here, we discuss briefly the relationship between the p-rationality level of a character and the action of Galois automorphisms. The notation here will often be referred to throughout.
Let G be a finite group and suppose that
$|G|=n=p^bm$
with
$(p,m)=1$
. Let
${\mathcal {G}:=\mathrm {Gal}({\mathbb Q}_n/{\mathbb Q})}$
. Then,
$$\begin{align*}\mathcal{G}\cong\mathcal{I}\times \mathcal{K},\end{align*}$$
where
$$\begin{align*}\mathcal{I}=\mathrm{Gal}({\mathbb Q}_n/{\mathbb Q}_m) \text{ and } \mathcal{K}=\mathrm{Gal}({\mathbb Q}_n/{\mathbb Q}_{p^b})\end{align*}$$
are the subgroups of
$\mathcal {G}$
of those automorphisms fixing
$p'$
-roots and p-power roots, respectively, of unity. Let
$$\begin{align*}\mathcal{H}:=\mathcal{I}\times \langle \sigma\rangle,\end{align*}$$
where
$\sigma \in \mathcal {K}$
is such that its restriction to
${\mathbb Q}_m$
is the Frobenius automorphism
$\zeta \mapsto \zeta ^p$
. The group
$\mathcal {H}$
is an important ingredient in the McKay–Navarro and AMN Conjectures [Reference Navarro26], which we will discuss further in § 7.
It is well known that the Galois group
$\mathcal {G}$
permutes the p-blocks of G. Let B be a p-block of G and
$\mathcal {H}_B$
be the subgroup of
$\mathcal {H}$
fixing B. Since
$\mathcal {I}$
point-wisely fixes
${\mathbb Q}_m$
, it fixes every Brauer character and thus every block of G. In particular,
$$\begin{align*}\mathcal{I}\leq \mathcal{H}_B.\end{align*}$$
We define
$\mathcal {I}':=\mathcal {I}$
if
$p=2$
and
$\mathcal {I}':=\mathrm {Gal}({\mathbb Q}_{n}/{\mathbb Q}_{pm})$
if
$p>2$
. Note that
$\mathcal {I}'$
is the Sylow p-subgroup of
$\mathcal {I}$
. Note also that if
$H_1$
and
$H_2$
are groups with orders dividing n, then characters
$\chi _1$
of
$H_1$
and
$\chi _2$
of
$H_2$
have the same p-rationality level whenever they have the same stabilizer under
$\mathcal {I}$
. Further, the same can be said, replacing
$\mathcal {I}$
with
$\mathcal {I}'$
, with the added assumption that
${\mathbf {lev}}(\chi _i)\geq 1$
for
$i=1,2$
if
$p>2$
.
In fact, as pointed out in [Reference Navarro and Tiep28, Section 4], there is one particular element of
$\mathcal {I}'$
that captures this behavior. Namely, for
$e\in {\mathbb Z}_{\geq 1}$
, let
$\sigma _e$
be the element of
$\mathcal {I}'$
mapping any p-power root of unity
$\omega $
to
$\omega ^{1+p^e}$
. The Galois automorphism
$\sigma _e$
has been seen to play a pivotal role in consequences of the McKay–Navarro conjecture predicting global-local properties of finite groups, and it turns out that the stability of a character under
$\sigma _e$
is closely tied to its p-rationality level (see [Reference Navarro and Tiep28, Lemma 4.1]).
3. Blocks of cyclic defect
The goal of this section is to prove Theorem C.
3.1. Small-defect blocks
We begin with an elementary upper bound for the p-rationality level in terms of a defect group, which allows us to easily control the level of characters in blocks of small defect.
Recall that if B is a p-block of a finite group G then its defect
$d(B)$
is the nonnegative integer
$$\begin{align*}{d(B)}:=\nu(|G|)-\min_{\psi\in{\mathrm {Irr}}(B)}\{\nu(\psi(1))\}.\end{align*}$$
Moreover, the order of any defect group D of B is
$|D|=p^{d(B)}$
. We will also denote by
$\mathrm {exp}(D)$
the exponent of D.
Throughout, for an integer n, we will write
$n_p$
and
$n_{p'}$
for its p- and
$p'$
-parts, respectively, so that
$n=n_pn_{p'}$
,
$n_p$
is a power of p, and
$(p, n_{p'})=1$
. Similarly, for an element g of a finite group G, we will write
$g_p$
and
$g_{p'}$
for the (unique) elements such that
$g=g_pg_{p'}$
with
$|g_p|=|g|_p$
and
$|g_{p'}|=|g|_{p'}$
.
Lemma 3.1. Let
$\chi \in {\mathrm {Irr}}(G)$
and B the p-block of G containing
$\chi $
. Let D be a defect group of B. Then,
${\mathbf {lev}}(\chi )\leq \nu (\exp (D))$
. In particular,
${\mathbf {lev}}(\chi )\leq d(B)$
.
Proof. Let
$g\in G$
with
$\chi (g)\neq 0$
. Then,
$g_p$
belongs to a conjugate of D by [Reference Navarro24, Corollary 5.9]. Therefore,
$|g|_p\leq \exp (D)$
, and we have
$$\begin{align*}\chi(g)\in{\mathbb Q}_{|g|}\subseteq {\mathbb Q}_{|g|_p|g|_{p'}}\subseteq {\mathbb Q}_{\exp(D)|G|_{p'}}.\end{align*}$$
We now have
${\mathbb Q}(\chi )\subseteq {\mathbb Q}_{\exp (D)|G|_{p'}}$
, which implies that
$c(\chi )$
divides
$\exp (D)|G|_{p'}$
, and the lemma follows.
Corollary 3.2. Let
$\chi \in {\mathrm {Irr}}(G)$
belong to a p-block of defect 0, or defect 1 if
$p=2$
. Then,
${\mathbf {lev}}(\chi )=0$
.
Proof. This follows from Lemma 3.1. Note that
${\mathbb Q}_n={\mathbb Q}_{2n}$
for odd n, so there are no characters of
$2$
-rationality level
$1$
.
Lemma 3.3. Let p be an odd prime. Suppose
$\chi \in {\mathrm {Irr}}(G)$
belongs to a p-block of defect one with a defect group D. Then,
${\mathbf {lev}}(\chi )\in \{0,1\}$
and
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
.
Proof. The first conclusion again follows from Lemma 3.1, so it remains to prove the second part. We have
$\chi (1)_p=|G|_p/p$
and
$\mathbf {ht}(\chi )=0$
. p-Blocks of defect one have been fully described in early work of Brauer [Reference Brauer1], [Reference Brauer2] (see also [Reference Navarro24, Chapter 11]). Let
$K:={\mathbf {O}}_{p'}({\mathbf {N}}_G(D))$
. Let
$b\in \mathrm {\mathrm {Bl}}({\mathbf {C}}_G(D))$
be a root of B and
$\xi \in {\mathrm {Irr}}(K)$
be the restriction (to K) of the canonical character in
${\mathrm {Irr}}(b)$
of B. In fact,
$\xi $
is the unique Brauer character in b. Let E be the subgroup of
${\mathbf {N}}_G(D)$
fixing b and
$\overline {E}:=E/{\mathbf {C}}_G(D)$
the inertial quotient of B and
$e:=|\overline {E}|$
. The block B then contains precisely
$e+(p-1)/e$
ordinary irreducible characters, where e of these are p-rational and, therefore, trivially satisfy the stated equality.
Suppose that
$\chi $
is one of the remaining
$(p-1)/e$
other characters, a so-called exceptional character. In this case, there exists
$\lambda \in {\mathrm {Irr}}(D)-\{1_D\}$
and
$\epsilon \in \{\pm 1\}$
such that
$$\begin{align*}\chi(hk)=\epsilon(\lambda\times \xi)^{{\mathbf{N}}_G(D)}(hk) \end{align*}$$
for every
$h\in D-\{1\}$
and
$k\in K$
, by [Reference Navarro24, Chapter 11]. Note that
$\chi (g)=0$
whenever
$g_p$
is not conjugate to an element in D. Also, for each
$h\in D-\{1\}$
, a
$p'$
-element in
${\mathbf {C}}_G(h)$
must be inside K. Therefore, these elements
$hk$
capture all the non-zero values of
$\chi $
. It follows that
${\mathbb Q}(\chi )={\mathbb Q}(\chi _{D\times K})$
, and thus
${\mathbb Q}(\chi )={\mathbb Q}(\chi _{{\mathbf {N}}_G(D)})$
, as desired.
3.2. Generalities on blocks with cyclic defect groups
To prove Theorem C for blocks of larger cyclic defect, we need to recall some basics on cyclic-defect theory, and refer the reader to [Reference Dade6] and [Reference Feit8, Chapter VII] for more details. The theory, developed by E. Dade in the sixties, generalizes Brauer’s work on defect-one blocks mentioned above.
Let B be a block of a finite group G with cyclic defect group D of order
$p^a$
(
$a\geq 1$
). Let
$B_0\in \mathrm {\mathrm {Bl}}({\mathbf {N}}_G(D))$
be the Brauer correspondent of B and
$b_0\in \mathrm {\mathrm {Bl}}({\mathbf {C}}_G(D))$
be a root of B; that is,
$b_0^{{\mathbf {N}}_G(D)}=B_0$
. Let
$C:={\mathbf {C}}_G(D)$
and let E be the subgroup of
${\mathbf {N}}_G(D)$
fixing
$b_0$
. The inertial quotient
$E/C$
is then a cyclic group of
$p'$
-order acting Frobeniusly on D (as well as
${\mathrm {Irr}}(D)$
). Let
$\Lambda $
be a complete set of representatives of the action of E on
${\mathrm {Irr}}(D)-\{1_D\}$
. Then,
$|\Lambda |=(p^a-1)/e$
, where
$e:=|E/C|$
.
If
$|\Lambda |=1$
, then D must have order p and B has precisely
$e+1$
irreducible ordinary characters. Suppose that
$|\Lambda |>1$
. Then,
${\mathrm {Irr}}(B)$
is partitioned into two naturally defined subsets
${\mathrm {Irr}}_{nex}(B)$
and
${\mathrm {Irr}}_{ex}(B)$
. The former consists of precisely e non-exceptional characters
$\{X_1,...,X_e\}$
. The latter consists of precisely
$|\Lambda |$
exceptional characters, which are naturally labeled by the members of
$\Lambda $
:
$$\begin{align*}{\mathrm {Irr}}_{ex}(B)=\{X_\lambda\mid \lambda\in\Lambda\}.\end{align*}$$
As noted in [Reference Navarro26, p. 1135], the group
$\mathcal {H}_B$
permutes the exceptional/non-exceptional characters among themselves.
For
$0\leq i\leq a$
, let
$D_i$
be the (unique) subgroup of D containing the elements of order at most
$p^{a-i}$
; that is,
$$\begin{align*}D_i \text{ is the subgroup of } D \text{ with } |D:D_i|=p^i.\end{align*}$$
Let
$$\begin{align*}C_i:={\mathbf{C}}_G(D_i) \text{ and } N_i:={\mathbf{N}}_G(D_i).\end{align*}$$
Assume now that
$0\leq i\leq a-1$
. By [Reference Dade6, Proposition 1.6], the block
$b_i:=(b_0)^{C_i}\in \mathrm {\mathrm {Bl}}(C_i)$
contains a unique Brauer character, say
$\varphi _i$
. By [Reference Dade6, Corollary 1.9], for
$x\in D_i-D_{i+1}$
, and y a p-regular element of
$C_i$
, we have for each
$\lambda \in \Lambda $
,
$$ \begin{align} X_\lambda(xy)=\frac{\delta}{|C_i|} \sum_{h\in N_i} \lambda^h(x)(\varphi_i)^h(y), \end{align} $$
for some
$\delta \in \{\pm 1\}$
depending only on i; and for each
$1\leq j\leq e$
,
$$\begin{align*}X_j(xy)=\frac{\pm1}{e|C_i|} \sum_{h\in N_i} (\varphi_i)^h(y). \end{align*}$$
We remark that, if
$\chi \in {\mathrm {Irr}}(G)$
and
$g\in G$
, then
$\chi (g)$
is a sum of
$|g|$
-th roots of unity. The nonexceptional characters
$X_j$
are therefore always p-rational.
3.3. Proof of Theorem C
We are ready to prove Theorem C, which we now restate.
Theorem 3.4. Let p be a prime and G a finite group. Let
$B\in \mathrm {\mathrm {Bl}}(G)$
be a p-block of G with cyclic defect group D. Then,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
for every
$\chi \in {\mathrm {Irr}}(B)$
.
Proof. The case of defect zero follows from Corollary 3.2. We may assume that
$|D|>1$
.
We shall follow the notation described above. If
$|\Lambda |=1$
then, as mentioned already, the block B must have defect one, and we are done by Corollary 3.2 and Lemma 3.3. So we assume from now on that
$|\Lambda |>1$
. If
$\chi \in {\mathrm {Irr}}_{nex}(B)$
is a non-exceptional character of B, then
$\chi $
is p-rational, and thus there is nothing to prove. We, therefore, assume furthermore that
$\chi $
is one of the exceptional characters
$X_\lambda $
for some
$ \lambda \in \Lambda $
.
We claim that
$$\begin{align*}\text{if } {\mathbf{lev}}(X_\lambda)\geq 1, \text{ then } {\mathbf{lev}}(X_\lambda)={\mathbf{lev}}(\lambda). \end{align*}$$
Let
$\widetilde {D}$
be the unique subgroup of D of order p and set
$\widetilde {N}:={\mathbf {N}}_G(\widetilde {D})$
. Let
$\widetilde {B}=(b_0)^{\widetilde {N}}=(B_0)^{\widetilde {N}}$
, which is a block of
$\widetilde {N}$
that has the same defect group D and Brauer correspondent
$B_0$
as B. Dade proved in [Reference Dade7, Lemma 4.9] that the exceptional characters of
$\widetilde {B}$
can be labeled by
${\mathrm {Irr}}_{ex}(\widetilde {B})=\{\widetilde {X}_\lambda \mid \lambda \in \Lambda \}$
so that the bijection
$X_\lambda \mapsto \widetilde {X}_\lambda $
from
${\mathrm {Irr}}_{ex}(B)$
to
${\mathrm {Irr}}_{ex}(\widetilde {B})$
satisfies
$(\widetilde {X}_{\lambda _1}-\widetilde {X}_{\lambda _2})^G=\delta (X_{\lambda _1}-X_{\lambda _2})$
for some fixed
$\delta \in \{\pm 1\}$
and every
$\lambda _1,\lambda _2\in \Lambda $
. As mentioned in the proof of [Reference Navarro26, Theorem 3.4], Dade’s bijection commutes with the action of
$\mathcal {H}_B$
, and hence preserves the p-rationality level. This allows us, for the purpose of proving the claim, to assume that
$\widetilde {D}\vartriangleleft G$
.
Let
$\widetilde {C}:={\mathbf {C}}_G(\widetilde {D})$
and
$\widetilde {b}:=(b_0)^{\widetilde {C}}$
. By [Reference Dade6, §4], the exceptional characters of B are induced from (nontrivial) ordinary irreducible characters of
$\widetilde {b}$
. In fact,
${\mathrm {Irr}}(\widetilde {b})$
consists of
$|D|$
characters
$\{\chi _\lambda \mid \lambda \in {\mathrm {Irr}}(D)\}$
and
$(\chi _{\lambda _1})^G=(\chi _{\lambda _2})^G$
if and only if
$\lambda _1=\lambda _2^z$
for some
$z\in E$
, so that
$$\begin{align*}{\mathrm {Irr}}_{ex}(B)=\{(\chi_\lambda)^G\mid \lambda\in\Lambda\} \text{ and } X_\lambda=(\chi_\lambda)^G.\end{align*}$$
It was shown in [Reference Navarro26, p. 1136], using the character-valued formula of
$\chi _\lambda $
in [Reference Dade6, Lemma 3.2], that a Galois automorphism
$\tau \in \mathcal {H}_B$
moves the character
$\chi _\lambda $
in
${\mathrm {Irr}}(\widetilde {b})$
to the character in
${\mathrm {Irr}}((\widetilde {b})^\tau )$
labeled by
$\chi _{\lambda ^\tau }$
. Recall the groups
$\mathcal {I}:=\mathrm {Gal}({\mathbb Q}_{|G|}/{\mathbb Q}_{|G|_{p'}})\leq \mathcal {H}_B$
and the p-subgroup
$\mathcal {I}'\leq \mathcal {I}$
from §2. Note that every relevant block is point-wisely fixed by
$\mathcal {I}$
. It follows that, for every
$\tau \in \mathcal {I}$
,
$(\chi _\lambda )^\tau =\chi _{\lambda ^\tau }, $
which implies that
$$\begin{align*}{\mathbf{lev}}(\chi_\lambda)={\mathbf{lev}}(\lambda). \end{align*}$$
Further, recall that to show
${\mathbf {lev}}(X_\lambda )={\mathbf {lev}}(\lambda )$
, it suffices to show they are stable under the same elements of
$\mathcal {I}'$
, assuming that
${\mathbf {lev}}(X_\lambda )\geq 1$
if
$p\neq 2$
.
For each
$\tau \in \mathcal {I}'$
, we have
$$\begin{align*}X_\lambda^\tau=\left((\chi_\lambda)^G\right)^\tau=\left((\chi_\lambda)^\tau\right)^G=(\chi_{\lambda^\tau})^G. \end{align*}$$
Therefore,
$(\chi _\lambda )^G$
is
$\tau $
-invariant if and only if
$(\chi _\lambda )^G=(\chi _{\lambda ^\tau })^G$
, which is equivalent to
$\lambda ^\tau =\lambda ^z$
for some
$z\in E$
. We may assume that z has
$p'$
-order, because
$E/C$
has
$p'$
-order and C fixes every irreducible character of D. Further, note that the actions of z and of
$\tau $
commute. Let
$t:=|\tau |$
be the order of
$\tau $
, which is a p-power. Then,
$\lambda =\lambda ^{\tau ^t}=\lambda ^{z^t}$
. Thus,
$z^t\in C$
as
$E/C$
acts Frobeniusly on
${\mathrm {Irr}}(D)$
. But
$|z|$
and t are coprime, so
$z\in C$
and
$\lambda ^\tau =\lambda $
. We indeed have shown that, for every
$\lambda \in \Lambda $
,
$$\begin{align*}\text{if } p=2, \text{ then } {\mathbf{lev}}(X_\lambda)={\mathbf{lev}}(\lambda) \end{align*}$$
and
$$\begin{align*}\text{if } p>2 \text{ and } {\mathbf{lev}}(X_\lambda)\geq 1, \text{ then } {\mathbf{lev}}(X_\lambda)={\mathbf{lev}}(\lambda). \end{align*}$$
The proof of the claim is completed.
Note that the desired equality
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})={\mathbf {lev}}(\chi )$
is obvious when
$\chi $
is p-rational. By the above claim, it suffices to prove the equality for those characters
$X_\lambda $
with
${\mathbf {lev}}(X_\lambda )={\mathbf {lev}}(\lambda )\geq 1$
. For convenience, let
$\ell :={\mathbf {lev}}(\lambda )$
. Since
${\mathbf {lev}}(X_\lambda )=\max \{{\mathbf {lev}}(X_\lambda (g)): g\in G\}$
, there exists some
$g\in G$
such that
$$\begin{align*}{\mathbf{lev}}(X_\lambda(g))={\mathbf{lev}}(X_\lambda)={\mathbf{lev}}(\lambda)=\ell. \end{align*}$$
Our job now is to show that such an element g can be chosen to be inside
${\mathbf {N}}_G(D)$
. In fact, we will see that, up to conjugation, this must be the case.
Note that
$X_\lambda $
takes value 0 on every element whose p-part is not conjugate to an element of D. For our purpose of analyzing the value
$X_\lambda (g)$
, we may, therefore, assume that
$g_p\in D$
. We next claim that
$g_p\in D_0-D_1$
, so that
$g_p$
generates D.
Assume, to the contrary, that
$g_p\in D_1$
; that is,
$|g_p|\leq p^{a-1}$
. Then, there exists
$1\leq i\leq a-1$
such that
$|g_p|=p^{a-i}$
and
$g_p\in D_i-D_{i+1}$
. Now
$(g_p)^h\in D_i-D_{i+1}$
for every
$h\in N_i$
. We have
$$\begin{align*}{\mathbf{lev}}(\lambda^h(g_p))={\mathbf{lev}}(\lambda((g_p)^{h^{-1}}))= \begin{cases} \ell-i &\text{ if } i\leq \ell,\\ 0 &\text{ if } i>\ell \end{cases}\end{align*}$$
for every
$h\in N_i$
. In any case,
$$\begin{align*}{\mathbf{lev}}(\lambda^h(g_p))\leq \ell-1. \end{align*}$$
By the character-valued formula (3.1),
$$\begin{align*}X_\lambda(g)=\frac{\delta}{|C_i|} \sum_{h\in N_i} \lambda^h(g_p)(\varphi_i)^h(g_{p'})\end{align*}$$
for some
$\delta \in \{\pm 1\}$
. Note that each value
$(\varphi _i)^h(g_{p'})$
is p-rational. It follows that
$X_{\lambda }(g)$
, being a sum of complex numbers of level at most
$\ell -1$
, must have level at most
$\ell -1$
, which is a contradiction.
We have shown that
$g_p\in D_0-D_1$
. In other words,
$g_p$
is a generator for D. Thus,
$$\begin{align*}g_{p'}\in {\mathbf{C}}_G(g_p)={\mathbf{C}}_G(D) \subseteq {\mathbf{N}}_G(D),\end{align*}$$
and it follows that
$$\begin{align*}g=g_pg_{p'}\in {\mathbf{N}}_G(D).\end{align*}$$
Let
$\chi :=X_\lambda $
. We then have
$$\begin{align*}\ell={\mathbf{lev}}(\chi(g))\leq {\mathbf{lev}}(\chi_{{\mathbf{N}}_G(D)})\leq{\mathbf{lev}}(\chi)=\ell,\end{align*}$$
implying that
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})={\mathbf {lev}}(\chi )$
. The proof is complete.
Remark 3.5. Our proof of Theorem C indeed shows that, in view of Remark 1.1, if a group element captures the p-rationality of the character, then that element must lie inside the defect normalizer, up to conjugation. At the moment, we do not know if this is true for arbitrary defect.
We conclude this section with the confirmation of Conjecture A for all characters in blocks of defect at most 2.
Proposition 3.6. Let p be a prime, G a finite group, and
$\chi $
be a height-zero character in a block B of G with
${\mathbf {lev}}(\chi )\geq 2$
and
$d(B)\leq 2$
. Suppose that D is a defect group of B. Then,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
.
4. Imprimitive characters of prime degree
This section proves Theorem D in the case, where the character in question is imprimitive. Recall that a character
$\chi \in {\mathrm {Irr}}(G)$
is termed imprimitive if there exists a subgroup
$H<G$
and
$\psi \in {\mathrm {Irr}}(H)$
such that
$\chi =\psi ^G$
.
We shall need a p-local invariant of characters that was introduced recently in Isaacs–Navarro’s solution [Reference Isaacs and Navarro20] of Conjecture B for p-solvable groups.
Definition 4.1. For a character
$\Psi $
(not necessarily irreducible) of a finite group G and a nonnegative integer i, let
$$\begin{align*}\Delta_i(\Psi):=\sum_{\substack{\chi\in{\mathrm {Irr}}(G)\\ {\mathbf{lev}}(\chi)=i}} [\chi,\Psi] \chi \end{align*}$$
and, if one of
$\Delta _i(\Psi )(1)$
is not divisible by p,
$$\begin{align*}\ell(\Psi):=\max\{i\in{\mathbb Z}_{\geq 0}: \Delta_i(\Psi)(1) \not\equiv 0 \bmod p\}. \end{align*}$$
Lemma 4.2. Let
$\Psi $
be a character of a finite group G with
${\mathbf {lev}}(\Psi )=a$
. We have:
-
(i)
$\Delta _i(\Psi )(1)\equiv 0 \bmod p$
for every
$i\geq \max \{2,a+1\}$
. -
(ii) If
$a\geq 1$
, then
${\mathbf {lev}}(\Psi )\geq \ell (\Psi )$
.
Proof. Note that Part (ii) follows from (i), so it is sufficient to prove (i).
Clearly,
$|G|_p\geq p^a$
. Note that if
$p=2$
then
$a=0$
or is at least
$2$
. Let
$\mathcal {J}$
denote the (cyclic) p-group
$\mathrm {Gal}({\mathbb Q}_{|G|}/{\mathbb Q}_{p^a|G|_{p'}})$
if
$a>0$
or simply the p-group
$\mathrm {Gal}({\mathbb Q}_{|G|}/{\mathbb Q}_{p|G|_{p'}})$
if
$a=0$
. Then,
$\Psi $
is
$\mathcal {J}$
-invariant. Since
${\mathbb Q}(\psi ^\tau )={\mathbb Q}(\psi )$
for every character
$\psi $
of G and every
$\tau \in \mathcal {J}$
, each
$\Delta _i(\Psi )$
is
$\mathcal {J}$
-invariant, and hence
$\mathcal {J}$
permutes the irreducible constituents of
$\Delta _i(\Psi )$
. Let
$i>a$
if
$a>0$
or
$i\geq 2$
if
$a=0$
. Then, each constituent of
$\Delta _i(\Psi )$
, of level i, is not
$\mathcal {J}$
-invariant, and thus belongs to a
$\mathcal {J}$
-orbit of nontrivial length, which is necessarily a nontrivial p-power. As the irreducible constituents of
$\Delta _i(\Psi )$
is a disjoint union of these orbits, the statement follows.
The next result makes use of some ideas in the proof of [Reference Isaacs and Navarro20, Theorem 3.5].
Lemma 4.3. Let
$P\leq K\leq G,$
where
$P\in {\mathrm {Syl}}_p(G)$
,
$\chi \in {\mathrm {Irr}}_{p'}(G)$
, and
$\psi \in {\mathrm {Irr}}(K)$
such that
$\chi =\psi ^G$
. Let
$i\in {\mathbb Z}_{\geq 2}$
. Then,
$$\begin{align*}\Delta_i(\chi_P)(1)\not\equiv 0 \bmod p \text { if and only if } \Delta_i(\psi_P)(1)\not\equiv 0 \bmod p. \end{align*}$$
In particular, if
$\max \{\ell (\chi _P),\ell (\psi _P)\}\geq 2$
then
$\ell (\chi _P)=\ell (\psi _P)$
.
Proof. Let X be a set of representatives for the double
$K-P$
cosets in G, so that
$$\begin{align*}G=\bigcup_{x\in X} KxP \end{align*}$$
is a disjoint union. We decompose
$$\begin{align*}X=X_1\cup X_2, \end{align*}$$
where
$X_1$
consists of those
$x\in X$
such that
$P\subseteq K^x$
and
$X_2$
is, of course, the complement of
$X_1$
in X. Using Mackey’s theorem (see [Reference Isaacs18, Problem 5.6]), we have
$$ \begin{align*} \chi_P=\sum_{x\in X} \left((\psi^x)_{K^x\cap P}\right)^P&= \sum_{x\in X_1} \left((\psi^x)_{K^x\cap P}\right)^P + \sum_{x\in X_2} \left((\psi^x)_{K^x\cap P}\right)^P\\ &= \sum_{x\in X_1} (\psi^x)_P + \sum_{x\in X_2} \left((\psi^x)_{K^x\cap P}\right)^P. \end{align*} $$
Therefore, for every
$i\in {\mathbb Z}_{\geq 0}$
,
$$\begin{align*}\Delta_i(\chi_P)=\sum_{x\in X_1} \Delta_i((\psi^x)_P) + \sum_{x\in X_2} \Delta_i(\left((\psi^x)_{K^x\cap P}\right)^P). \end{align*}$$
For each
$x\in X_2$
, note that
$K^x\cap P$
is a proper subgroup of P, and it follows from [Reference Isaacs and Navarro20, Lemma 3.1] that
$$\begin{align*}\Delta_i\left(\left((\psi^x)_{K^x\cap P}\right)^P\right)(1) \equiv 0 \bmod p, \end{align*}$$
for every
$i\geq 2$
. We now obtain
$$\begin{align*}\Delta_i(\chi_P)(1) \equiv \sum_{x\in X_1} \Delta_i((\psi^x)_P)(1) \bmod p. \end{align*}$$
Let
$x\in X_1$
. Note that
$\alpha $
is an irreducible constituent of
$\psi _P$
if and only in
$\alpha ^x$
is an irreducible constituent of
$(\psi ^x)_{P^x}$
, and
${\mathbf {lev}}(\alpha )={\mathbf {lev}}(\alpha ^x)$
. Thus, there is a natural bijection between irreducible constituents of
$\psi _P$
and
$(\psi ^x)_P$
preserving the p-rationality level. In particular,
$$\begin{align*}\Delta_i(\psi_P)(1)=\Delta_i((\psi^x)_P) \end{align*}$$
for every
$x\in X_1$
. The last congruence in the previous paragraph then yields
$$\begin{align*}\Delta_i(\chi_P)(1) \equiv |X_1|\cdot\Delta_i(\psi_P)(1) \bmod p. \end{align*}$$
Now, by [Reference Isaacs and Navarro20, Lemma 3.4], which states that
$|X_1|$
is not divisible by p, the lemma follows.
We can now prove Theorem D in the imprimitivity case.
Theorem 4.4. Let p be a prime and G be a finite group. Let
$\chi =\lambda ^G\in {\mathrm {Irr}}(G)$
for some linear character
$\lambda $
of a subgroup K of G of prime index not equal to p. Suppose
${\mathbf {lev}}(\chi )\geq 1$
. Then,
${\mathbb Q}_{p^{{\mathbf {lev}}(\chi )}}={\mathbb Q}_p(\chi _P)$
.
Proof. Since the conclusion is obvious when
${\mathbf {lev}}(\chi )=1$
, we assume that
$a:={\mathbf {lev}}(\chi )\geq 2$
. By the character-induction formula, we have
$$\begin{align*}{\mathbf{lev}}(\lambda)\geq {\mathbf{lev}}(\chi)=a. \end{align*}$$
On the other hand, since
$\lambda $
is linear, we have
${\mathbf {lev}}(\lambda _P)=\ell (\lambda _P)$
and
$$\begin{align*}{\mathbf{lev}}(\lambda)=\ell(\lambda_P)=\nu({\mathrm {ord}}(\lambda)). \end{align*}$$
Furthermore, using Lemmas 4.2 and 4.3, we obtain
$$\begin{align*}{\mathbf{lev}}(\chi_P)\geq \ell(\chi_P) \end{align*}$$
and
$$\begin{align*}\ell(\chi_P)=\ell(\lambda_P). \end{align*}$$
The displayed (in)equalities imply that
$a={\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)=\ell (\chi _P)$
.
Note that
${\mathbb Q}_p(\chi _P)\subseteq {\mathbb Q}_{p^a}$
(see [Reference Navarro and Tiep28, Lemma 7.1]). Let
$\tau \in \mathrm {Gal}({\mathbb Q}_{p^a}/{\mathbb Q}_p(\chi _P))$
. Since
${[{\mathbb Q}_{p^a}:{\mathbb Q}_p]=p^{a-1}}$
, we have that
$\tau $
has p-power order. Also,
$\tau $
fixes
$\chi _P$
, and hence
$\tau $
permutes the linear constituents of
$\chi _P$
of level a. As
$\ell (\chi _P)=a$
, it follows that
$\Delta _a(\chi _P)(1)\not \equiv 0 \bmod p$
, which implies that the number of the linear constituents of
$\chi _P$
of level a is not divisible by p. Therefore, one of them must be
$\tau $
-invariant, and, therefore,
$\tau $
fixes
${\mathbb Q}_{p^a}$
or, in other words,
$\tau $
is trivial. We have shown that
${\mathbb Q}_{p^a}={\mathbb Q}_p(\chi _P)$
, as desired.
5. Quasisimple groups
5.1. Theorem D for quasisimple groups
The main result of this section is the following, which proves Theorem D for quasisimple groups, when combined with Lemma 6.1 below and [Reference Navarro and Tiep28, Theorem A3]. This result will be used in §6 to prove Theorem D for primitive characters.
Theorem 5.1. Let M be a quasisimple group and
$\chi \in {\mathrm {Irr}}(M)$
be of prime degree with
${\mathbf {lev}}(\chi )\geq 2$
. Let p be a prime not equal to
$\chi (1)$
. Then,
$$\begin{align*}{\mathbf{lev}}(\chi)={\mathbf{lev}}(\chi_P),\end{align*}$$
where
$P\in {\mathrm {Syl}}_p(M)$
.
Our next result reduces us to the case that G is a group of Lie type defined in characteristic distinct from p.
Theorem 5.2. Let p be a prime and let G be a quasisimple group such that
$S=G/{\mathbf {Z}}(G)$
is an alternating group, a sporadic simple group, a simple group of Lie type with exceptional Schur multiplier, or a simple group of Lie type defined in characteristic p. Let
$\chi \in \mathrm {Irr}(G)$
have height zero, lie in a block with nontrivial defect group D, and be such that
${\mathbf {lev}}(\chi )\geq 2$
. Then,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _D)$
. In particular, Conjecture A and Theorem 5.1 hold in these cases.
Proof. When S is either a sporadic simple group or
$\textsf {A}_n$
with
$5\leq n\leq 7$
, we have
${\mathbf {lev}}(\chi )\leq 1$
for all primes p and all
$\chi \in \mathrm {Irr}(G)$
of height zero, which can be readily checked in [11]. If S is a group of Lie type with exceptional Schur multiplier or the Tits group
${}^2\operatorname {F}_4(2)'$
, we see using [11] that
${\mathbf {lev}}(\chi )\leq 1$
for all height-zero characters of G except when
$p=2$
and
$S={\mathrm {PSL}}_3(4)$
with
$4\mid |\mathbf {Z}(G)|$
;
$S=\operatorname {B}_3(3)$
with
$2\mid |\mathbf {Z}(G)|$
;
$S={\mathrm {PSU}}_4(3)$
with
$4\mid |\mathbf {Z}(G)|$
; or
$S={}^2\operatorname {F}_4(2)'$
. In the latter cases,
${\mathbf {lev}}(\chi )\leq 2$
, and we in fact see using [11] that for every
$\chi \in {\mathrm {Irr}}(G)$
and for every prime
$p\mid |G|$
, we have
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _D)$
.
If
$p=2$
and S is
$\textsf {A}_n$
, then every irreducible character of S is p-rational (see [Reference Hung and Tiep16, §3] for instance), and we are done. Now consider the case
$p=2$
and S is a simple group of Lie type defined in characteristic
$2$
with nonexceptional Schur multiplier. Note that by [Reference Humphreys13], the blocks with positive defect are in fact of maximal defect. That is, the nontrivial defect groups are Sylow
$2$
-subgroups in this case. Then, we have
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _D)$
by [Reference Navarro and Tiep28, Theorem A3].
Finally, suppose that p is odd and G is a cover of an alternating group
$\textsf {A}_n$
with
$n\geq 8$
or a quasisimple group of Lie type that is a quotient of
${\mathbf {G}}^F$
for some simple, simply connected algebraic group
${\mathbf {G}}$
over a field of characteristic p and a Steinberg endomorphism
$F:{\mathbf {G}}\rightarrow {\mathbf {G}}$
. It was shown in [Reference Navarro and Tiep28, Theorem 6.1] that, in this situation,
$$\begin{align*}{\mathbb Q}(\chi)\subseteq {\mathbb Q}_{|G|_{p'}}(\sqrt{p}) \end{align*}$$
for every
$\chi \in {\mathrm {Irr}}(G)$
. As
${\mathbb Q}_{|G|_{p'}}$
contains a primitive
$4$
th root of unity and the conductor of
$\sqrt {(-1)^{(p-1)/2}p}$
is p, it follows that
$c(\chi )$
divides
$p|G|_{p'}$
. Then,
${\mathbf {lev}}(\chi )\leq 1$
and the conjecture trivially holds in this case.
We are now ready to complete the proof of Theorem 5.1.
Proof of Theorem 5.1
By Theorem 5.2, we may assume that
$S=M/\mathbf {Z}(M)$
is a simple group of Lie type defined in characteristic
$q_0\neq p$
, and that S has non-exceptional Schur multiplier. Further, we assume that p is odd, since the statement follows from [Reference Navarro and Tiep28, Theorem A3] if
$p=2$
.
Now, [Reference Hung, Tiep and Zalesski17, Theorem 4.2] gives a list of the possible
$(S, r)$
in this case, where
$r=\chi (1)$
is the prime for which M has an irreducible character of degree r. By our assumptions, we are not in the cases listed in (i) or (vi) of [Reference Hung, Tiep and Zalesski17, Theorem 4.2]. Then, S is one of:
$$\begin{align*}{\mathrm {PSL}}_2(q), {\mathrm {PSU}}_n(q) (n\geq 3), {\mathrm {PSL}}_n(q) (n\geq 3), \text{ or } {\mathrm {PSp}}_{2n}(q),\end{align*}$$
with specifications on
$n, q, r$
, and
$\chi $
in each case. Here, we have
$S=G/\mathbf {Z}(G)$
and
$M=G/Z$
for some
$Z\leq \mathbf {Z}(G)$
and
$G:={\mathbf {G}}^F$
, where
${\mathbf {G}}$
is a simple, simply connected algebraic group and
$F\colon {\mathbf {G}}\rightarrow {\mathbf {G}}$
is a Frobenius endomorphism defining
${\mathbf {G}}$
over
${\mathbb F}_q$
, where q is some power of
$q_0$
. We discuss each case separately.
(I) First, suppose we are in case (ii) of [Reference Hung, Tiep and Zalesski17, Theorem 4.2], so
$S={\mathrm {PSL}}_2(q)$
. Then, either
$r=q=q_0$
and
$\chi $
is the Steinberg character, which is rational; or q is odd and
$\chi (1)=r=\frac {q-\epsilon }{2}$
for some
$\epsilon \in \{\pm 1\}$
; or q is a power of
$2$
and
$r=q+\epsilon $
for some
$\epsilon \in \{\pm 1\}$
is a Mersenne prime or Fermat prime. In the case q is odd, we have
$c(\chi )\in \{q_0, 1\}$
as in [Reference Hung, Tiep and Zalesski17, §5.2.2], so
${\mathbf {lev}}(\chi )=0$
.
So, assume q is a power of
$2$
. Here, we have
${\mathbb Q}(\chi )\subseteq {\mathbb Q}_{q-\epsilon }$
, so we may assume
$p\mid (q-\epsilon )$
. In this case,
$\chi $
is the restriction of a semisimple character
$\widetilde \chi $
of
$\widetilde {G}={\mathrm {GL}}_2(q)$
indexed by a semisimple element with eigenvalues
$\{\zeta ^i, \zeta ^{-i}\}$
, where
$\zeta $
is a primitive
$(q-\epsilon )$
root of unity and
$1\leq i<q-\epsilon $
. Letting
$\alpha $
be a generator for
${\mathrm {Irr}}(C_{q-\epsilon })$
, we have
${\mathbb Q}(\chi )\subseteq {\mathbb Q}(\alpha ^i)$
, so that
${\mathbf {lev}}(\chi )\leq {\mathbf {lev}}(\alpha ^i)$
. Note that by [Reference Navarro and Tiep28, Lemma 4.1],
${\mathbf {lev}}(\chi )$
is the smallest positive integer e such that
$\chi ^{\sigma _e}=\chi $
, since p is odd. (Recall from §2 that
$\sigma _e\in \mathcal {I}'$
is the element mapping any p-power root of unity
$\omega $
to
$\omega ^{1+p^e}$
.)
Now, the value of
$\chi $
on a semisimple element
$g_j$
of
$S=G={\mathrm {SL}}_2(q)$
with eigenvalues
$\{\zeta ^j, \zeta ^{-j}\}$
is
$\zeta ^{ij}+\zeta ^{-ij}$
. In particular, taking
$m:=(q-\epsilon )_{p'}$
and
$h:=g_m$
, we have
$$\begin{align*}\chi(h)=\zeta^{im}+\zeta^{-im},\end{align*}$$
which is stable under
$\sigma _e$
if and only if
$\zeta ^{im}$
is, since p is odd. (This is worked out, for example, as in [Reference Peña, Pryor and Fry29, Lemma 2.1].) But this happens if and only if
$\alpha ^{im}$
, and hence
$\alpha ^i$
, is stable under
$\sigma _e$
. It follows that
$$\begin{align*}{\mathbf{lev}}(\alpha^i)={\mathbf{lev}}(\chi(h))\leq{\mathbf{lev}}(\chi).\end{align*}$$
This establishes that
$$\begin{align*}{\mathbf{lev}}(\alpha^i)= {\mathbf{lev}}(\chi)={\mathbf{lev}}(\chi|_P),\end{align*}$$
where P is a Sylow p-subgroup of S containing h.
(II) Next, suppose we are in case (iii) of [Reference Hung, Tiep and Zalesski17, Theorem 4.2], so that
$S={\mathrm {PSL}}_n(q)$
with n an odd prime,
$q=q_0^f\geq 3$
with
$q_0$
a prime and f odd, and
$r=(q^n-1)/(q-1)$
with
$(n,q-1)=1$
. Note that this means
$S=M=G$
. Here, as in [Reference Hung, Tiep and Zalesski17, §5.2.1], we have
$\chi $
is one of the
$q-2$
irreducible Weil characters of degree
$r=(q^n-1)/(q-1)$
. Note that
$\chi $
extends to an irreducible Weil character
$\widetilde \chi $
of
$\widetilde {G}:={\mathrm {GL}}_n(q)$
. Further,
$\chi $
is determined by the irreducible constituent of
$\widetilde \chi |_{\mathbf {Z}(\widetilde {G})}$
.
Let
$\alpha $
be a generator for
${\mathrm {Irr}}(\mathbf {Z}(\widetilde {G}))\cong C_{q-1}$
. Then, for
$i=1,\ldots , q-2$
, let
$\widetilde \chi _i$
be an irreducible Weil character of
$\widetilde {G}$
such that
$\widetilde {\chi }_i|_{\mathbf {Z}(\widetilde {G})}=\widetilde \chi _i(1)\alpha ^i$
. Then, any such choice of
$\widetilde \chi _i$
has the same restriction to G, and we let
$\chi _i:=\widetilde {\chi }_i|_{G}$
be that restriction. Let
$\widetilde \chi :=\widetilde \chi _i$
and
$\chi :=\chi _i$
. As discussed in [Reference Hung, Tiep and Zalesski17, §5.2.1], we have
${\mathbb Q}(\widetilde \chi _i)\subseteq {\mathbb Q}(\alpha ^i)$
, so that
$$\begin{align*}{\mathbb Q}(\chi)\subseteq {\mathbb Q}(\widetilde\chi)\subseteq {\mathbb Q}(\alpha^i)= {\mathbb Q}(\zeta^i)\subseteq {\mathbb Q}(\zeta),\end{align*}$$
where
$\zeta $
is a primitive
$(q-1)$
-root of unity in
$\overline {{\mathbb Q}}^\times $
. From this, we may assume
$p\mid (q-1)$
, as otherwise
${\mathbf {lev}}(\chi )=0$
.
Now, following [Reference Guralnick and Tiep12, p. 125], we see
$\widetilde \chi ={\operatorname {R}}_{L}^{\widetilde {G}}(\lambda )$
, where L is a Levi subgroup of the form
${\mathrm {GL}}_1(q)\times {\mathrm {GL}}_{n-1}(q)$
of
$\widetilde {G}$
,
$\lambda \in \mathrm {Irr}(L)$
is the character of a module of the form
$$\begin{align*}S(s,(1))\otimes S(t, (n-1))\end{align*}$$
in the notation of [Reference Guralnick and Tiep12, p. 125] with
$s\neq t\in {\mathbb F}_q^\times $
and
$s/t=\alpha ^i$
, and
${\operatorname {R}}_{L}^{\widetilde {G}}$
denotes Harish–Chandra induction. Here, by an abuse of notation, we also denote by
$\alpha $
a generator of
${\mathbb F}_q^\times \cong C_{q-1}$
. Since multiplying by a linear character of
$\widetilde {G}$
does not affect
$\chi _i$
, we may further assume that
$t=1$
, so
$$\begin{align*}\lambda=S(\alpha^i,(1))\otimes S(1, (n-1)).\end{align*}$$
(Note that for
$\alpha ^j\in {\mathbb F}_q^\times $
, the module
$S(\alpha ^j, (k))$
affords the inflation of the linear character
${\mathrm {GL}}_k(q)/{\mathrm {SL}}_k(q)\cong {\mathbb F}_q^\times \rightarrow \overline {{\mathbb Q}}^\times $
defined by
$\alpha \mapsto \zeta ^j$
.)
Now, let Q be a parabolic subgroup of
$\widetilde {G}$
such that
$L\leq Q$
is the Levi complement in Q, and let
$\hat \lambda $
be the inflation of
$\lambda $
to Q. Then,
$$\begin{align*}\chi={\mathrm {Res}}^{\widetilde{G}}_G{\mathrm {Ind}}_Q^{\widetilde{G}}(\hat\lambda)= {\mathrm {Ind}}_{Q\cap G}^G{\mathrm {Res}}_{Q\cap G}^Q(\hat\lambda)\end{align*}$$
since
$\widetilde {G}=GQ$
. Note that
$r=\chi (1)=[G:Q\cap G]$
. Then, by the first half of the proof of Theorem 4.4, we have
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)$
, as desired.
(III) Now consider case (iv) of [Reference Hung, Tiep and Zalesski17, Theorem 4.2]. Here,
$S={\mathrm {PSU}}_n(q)$
with n an odd prime,
$r=(q^n+1)/(q+1)$
, and
$(n,q+1)=1$
. Again, this means
$S=M=G$
and
$\chi $
is one of the q irreducible Weil characters of degree
$r=(q^n+1)/(q+1)$
(see [Reference Hung, Tiep and Zalesski17, §5.3]). Again,
$\chi $
extends to an irreducible Weil character
$\widetilde \chi $
of
$\widetilde {G}:={\mathrm {GU}}_n(q)$
and
$\chi $
is determined by its values on
$\mathbf {Z}(\widetilde {G})$
. Letting
$\alpha $
be a generator for
${\mathrm {Irr}}(\mathbf {Z}(\widetilde {G}))\cong C_{q+1}$
, we have Weil characters
$\chi _i=\widetilde \chi _i|_{G}$
, where
$\widetilde \chi _i|_{\mathbf { Z}(\widetilde {G})}=\widetilde \chi _i(1)\alpha ^i$
as in (II), now for
$i=1,\ldots , q$
. Here, we similarly have
${\mathbb Q}(\chi _i)\subseteq {\mathbb Q}(\alpha ^i)\subseteq {\mathbb Q}(\xi )$
, where
$\xi $
is a primitive
$(q+1)$
-root of unity in
$\overline {{\mathbb Q}}^\times $
. So, we assume
$p\mid (q+1)$
. Further, this establishes that
$$\begin{align*}{\mathbf{lev}}(\chi_i)\leq {\mathbf{lev}}(\alpha^i).\end{align*}$$
In this case, we use the explicit formula from [Reference Tiep and Zalesski33, Theorem 4.1] for the values of
$\chi _i$
. Namely, for
$g\in \widetilde {G}$
, we have
$$\begin{align*}\chi_i(g)=\frac{(-1)^n}{q+1}\sum_{k=0}^q\xi^{-ik}(-q)^{\dim\mathrm{Ker}(g-\hat\xi^{-k})},\end{align*}$$
where
$\hat \xi $
denotes a generator of the subgroup
$C_{q+1}\leq {\mathbb F}_{q^2}^\times $
.
Now, let
$m:=(q+1)_{p'}$
and let
$\beta :=\hat \xi ^{m}$
be a generator of the Sylow p-subgroup of
$C_{q+1}\leq {\mathbb F}_{q^2}^\times $
. Let h be a semisimple p-element of G with eigenvalues
$\{\beta , \beta ^{-1}, 1,\ldots ,1\}$
. Then, since n and p are odd, we have:
$$\begin{align*}\chi_i(h)&=\frac{-1}{q+1}\left((\xi^{im}+\xi^{-im})(-q)+(-q)^{n-2}- \xi^{im}-\xi^{-im}+\sum_{k=1}^q \xi^{-ik} \right)\\&=(\xi^{im}+\xi^{-im})+\frac{1}{q+1}\left(q^{n-2}-\sum_{k=1}^q \xi^{-ik} \right)=(\xi^{im}+\xi^{-im})+\frac{q^{n-2}+1}{q+1}.\end{align*}$$
Recall again that by [Reference Navarro and Tiep28, Lemma 4.1],
${\mathbf {lev}}(\chi )$
is the smallest positive integer e such that
$\chi ^{\sigma _e}=\chi $
, since p is odd. From above, we see
$\chi _i(h)$
is fixed by
$\sigma _e$
if and only if
$(\xi ^{im}+\xi ^{-im})$
is fixed by
$\sigma _e$
. From here, we conclude similar to (I). Namely,
$\chi _i(h)$
is then stable under
$\sigma _e$
if and only if
$\xi ^{im}$
is stable under
$\sigma _e$
, if and only if the character
$\alpha ^{im}$
is stable under
$\sigma _e$
, so also
$\alpha ^i$
is. So we have
${\mathbf {lev}}(\chi _i(h))={\mathbf {lev}}(\alpha ^i)$
. Then,
$$\begin{align*}{\mathbf{lev}}(\chi_i)\geq {\mathbf{lev}}(\alpha^i),\end{align*}$$
forcing that
$$\begin{align*}{\mathbf{lev}}(\alpha^i)= {\mathbf{lev}}(\chi_i)={\mathbf{lev}}(\chi_i|_P),\end{align*}$$
where P is a Sylow p-subgroup of S containing h.
(IV) Finally, assume we are in case (v) of [Reference Hung, Tiep and Zalesski17, Theorem 4.2]. Then,
$S={\mathrm {PSp}}_{2n}(q)$
and either
-
(a)
$r=(q^n+1)/2$
with
$n=2^a\geq 2$
and
$q=q_0^{2^k}$
with
$q_0$
odd and
$k\geq 0$
; or -
(b)
$r=(3^n-1)/2$
, where n is an odd prime and
$q=3$
.
In case (a), we have as in [Reference Hung, Tiep and Zalesski17, §5.4.1] that either q is a square and hence
$\chi $
is rational-valued, or
$k=0$
so
$q=q_0$
and
${\mathbb Q}(\chi )\subseteq {\mathbb Q}(\zeta _{q})$
, where
$\zeta _{q}$
is a primitive qth root of unity in
$\overline {{\mathbb Q}}^\times $
. Then,
$\chi $
is almost p-rational (hence has
${\mathbf {lev}}(\chi )\leq 1$
) if
$p=q_0$
and is p-rational (so
${\mathbf {lev}}(\chi )=0$
) if
$p\neq q_0$
. In case (b), we similarly have
${\mathbb Q}(\chi )\subseteq {\mathbb Q}(\zeta _3)$
with
$\zeta _{3}$
a primitive
$3$
rd root of unity. Again,
${\mathbf {lev}}(\chi )\leq 1$
if
$p=3$
and
${\mathbf {lev}}(\chi )=0$
if
$p\neq 3$
.
5.2. Further examples satisfying Conjecture A
We provide further evidence for Conjecture A among certain (almost)-quasisimple groups.
When
$G={\mathbf {G}}^F$
, where
${\mathbf {G}}$
is a connected reductive algebraic group over
$\overline {\mathbb {F}}_{q_0}$
for a prime
$q_0$
and
$F\colon {\mathbf {G}}\rightarrow {\mathbf {G}}$
is a Steinberg morphism, the set
${\mathrm {Irr}}(G)$
is partitioned into so-called rational Lusztig series
$\mathcal {E}(G, s)$
. Here, s ranges over semisimple elements, up to
$G^{\ast }$
-conjugacy, of
$G^{\ast }=({\mathbf {G}}^{\ast })^{F^{\ast }}$
, where
$({\mathbf {G}}^{\ast }, F^{\ast })$
is dual to
$({\mathbf {G}}, F)$
. Let
$p\neq q_0$
be a nondefining prime and suppose that
$s\in G^{\ast }$
is a semisimple element of order relatively prime to p. Then, we define
$\mathcal {E}_p(G,s)$
to be the union of all
$\mathcal {E}(G, st)$
where
$t\in \mathbf {C}_{G^{\ast }}(s)$
is a p-element. A result of Digne and Michel yields that the set
$\mathcal {E}_p(G, s)$
is a union of p-blocks. (See [Reference Cabanes and Enguehard4, Theorem 9.12].)
Our next examples concerning Conjecture A are the Suzuki and Ree groups. That is, these are the cases that F is not a Frobenius morphism.
Theorem 5.3. Conjecture A holds for
${}^2\operatorname {B}_2(q^2)$
for
$q^2=2^{2n+1}>2$
and
${}^2\operatorname {G}_2(q^2)$
for
$q^2=3^{2n+1}>3$
. Further, if Conjecture B holds for
${}^2\operatorname {F}_4(q^2)$
, where
$q^2=2^{2n+1}>2$
, then Conjecture A holds for
${}^2\operatorname {F}_4(q^2)$
for
$p\neq 3$
.
Proof. By Theorems 5.2 and 3.4, we may assume that p is not the defining characteristic for G and that the Sylow p-subgroups of G are non-cyclic. Then, we are left to consider the case that
$G={}^2\operatorname {F}_4(q^2)$
with
$q^2=2^{2n+1}$
and p is an odd prime dividing
$ (q^2-1)$
,
$(q^2+1)$
, or
$(q^4+1)$
.
If
$p\nmid (q^2-1)$
[Reference Malle22, Bemerkung 1] yields that each
$\mathcal {E}_p(G, s)$
for
$s\in G^{\ast }$
a semisimple
$p'$
-element contains a unique block of positive defect, which, therefore, has as defect groups a Sylow p-subgroup of
$\mathbf {C}_{G^{\ast }}(s)$
, using [Reference Kessar and Malle21, Lemma 2.6]. If instead
$p\mid (q^2-1)$
, we have by [Reference Malle22, Bemerkung 1] that each
$\mathcal {E}_p(G, s)$
has one or three blocks of positive defect, but only one of these is noncyclic. In either case, a block B with non-cyclic defect groups has maximal defect for
$p\neq 3$
, completing the proof by our assumption that Conjecture B holds.
Our next several examples will come from linear groups, especially in the case
$p=2$
. Let
$\widetilde {G}:={\mathrm {GL}}_n( q)$
,
$G={\mathrm {SL}}_n(q)$
, and
$S={\mathrm {PSL}}_n(q)$
, and assume that q is odd and
$p=2$
.
In this situation, consider a block
$\widetilde {B}$
of
$\widetilde {G}$
covering a block B of G. These can be chosen so that
$\widetilde {B}= \mathcal {E}_2(\widetilde {G}, \widetilde {s})$
for some odd-order semisimple element
$\widetilde {s}$
of
$\widetilde {G}^{\ast }\cong \widetilde {G}$
, by [Reference Cabanes and Enguehard4, Theorems 9.12 and 21.14]. Further, a Sylow
$2$
-subgroup of
$\mathbf {C}_{\widetilde {G}^{\ast }}(s)$
gives a defect group for
$\widetilde {B}$
by [Reference Fong and Srinivasan9, Corollary (5E)]. (See also [Reference Broué3], which shows the results of [Reference Fong and Srinivasan9] also hold for
$p=2$
.) Now,
$\mathbf {C}_{\widetilde {G}^{\ast }}(\widetilde s)$
is a product
$\mathbf {C}_{\widetilde {G}^{\ast }}(\widetilde s)=\prod {\mathrm {GL}}_{m_i}(q^{d_i})$
, where
$m_i$
and
$d_i$
correspond to the multiplicities and degrees of the eigenvalues of
$\widetilde {s}$
and
$n=\sum m_id_i$
.
Theorem 5.4. Let M be a quasisimple group with
$M/\mathbf {Z}(M)={\mathrm {PSL}}_2(q)$
, where
$q\geq 5$
is a prime power. Then, Conjecture A holds for M.
Proof. Let q be a power of a prime
$q_0$
. In this case, the Sylow p-subgroups of M are cyclic unless
$p\in \{2,q_0\}$
. So, we may assume by Theorems 3.4 and 5.2 that
$p=2$
and by [Reference Navarro and Tiep28, Theorem A3] we need only consider blocks of M with non-maximal defect. We have
$M\in \{G, S\}$
, where
$G={\mathrm {SL}}_2(q)$
and
$S={\mathrm {PSL}}_2(q)$
. Let
$\widetilde {G}={\mathrm {GL}}_2(q)$
and let
$\bar B$
be a block of M with positive, non-maximal defect dominated by a block B of G. Let
$\widetilde {B}$
be a block of
$\widetilde {G}$
covering B. Then, as discussed above, there is some odd-order, semisimple element
$\widetilde s$
of
$\widetilde {G}^{\ast }\cong \widetilde G$
such that
$\widetilde {B}=\mathcal {E}_2(\widetilde {G}, \widetilde s)$
and a Sylow
$2$
-subgroup of
$\mathbf {C}_{\widetilde {G}^{\ast }}(\widetilde s)$
gives a defect group for
$\widetilde {B}$
. Then, with our assumption that
$\bar B$
is not of maximal defect, we see that any such defect group has cyclic intersection with G, so that B (hence
$\bar B$
) has cyclic defect groups. Then, we again apply Theorem 3.4.
Proposition 5.5. Let
$\widetilde {G}={\mathrm {GL}}_n(q)$
with q odd and let
$\widetilde {B}=\mathcal {E}_2(\widetilde {G}, \widetilde s)$
be a
$2$
-block of
$\widetilde {G}$
as discussed above. Further, suppose that
$q\equiv -1\pmod 4$
and that each
$d_i$
is odd, in the notation above. Then,
$\widetilde {B}$
satisfies Conjecture A.
Proof. Let D be a defect group for
$\widetilde {B}$
, such that
$D=\prod D_i$
with
$D_i\in \mathrm {Syl}_2({\mathrm {GL}}_{m_i}(q^{d_i}))$
. Note that in this case,
$q^{d_i}\equiv -1\pmod 4$
for each factor
${\mathrm {GL}}_{m_i}(q^{d_i})$
of
$C:=\mathbf { C}_{\widetilde {G}^{\ast }}(\widetilde s)$
.
We claim that in this situation, each
$D_i/D_i'$
has exponent at most
$2$
, and hence so does
$D/D'$
. We can see this from the description of Sylow
$2$
-subgroups of
${\mathrm {GL}}_{m}(q^d)$
in [Reference Carter and Fong5]. Indeed, by the description in [Reference Carter and Fong5], such a group is a direct product of Sylow
$2$
subgroups of
${\mathrm {GL}}_{2^j}(q)$
for various powers
$2^j$
of
$2$
. Hence, it suffices to prove the claim for m a power of
$2$
. A Sylow
$2$
-subgroup
$P_{2^j}$
of
${\mathrm {GL}}_{2^j}(q^d)$
is an iterated wreath product
$P_2\wr C_2\wr C_2\cdots \wr C_2$
, where
$P_2\in {\mathrm {Syl}}_2({\mathrm {GL}}_2(q^d))$
. Since the latter is semidihedral, we know
$\exp (P_2/P_2')\leq 2$
. For
$j\geq 2$
, we have
$P_{2^j}=P_{2^{j-1}}\wr C_2$
. Then,
$P_{2^j}/P_{2^{j}}'\cong P_{2^{j-1}}^2/\langle (P_{2^{j-1}}')^2, [P_{2^{j-1}}^2, C_2]\rangle \times C_2$
, and we can see inductively that
$\exp (P_{2^j}/P_{2^j}')\leq 2$
. This proves our claim. (See also [Reference Isaacs, Liebeck, Navarro and Tiep19, Proposition 4.3]).
Hence, by [Reference Isaacs, Liebeck, Navarro and Tiep19, Theorem D], each odd-degree character in the principal block
$B_0(C)$
of C is
$2$
-rational. But then the same is true for the height-zero characters of
$\widetilde {B}$
by the main Theorem of [Reference Srinivasan and Vinroot32], since these correspond to the height-zero characters in
$B_0(C)$
by Jordan decomposition using [Reference Fong and Srinivasan9, Theorem (7A)]. (See also [Reference Broué3], which shows the results of [Reference Fong and Srinivasan9] continue to hold for
$p=2$
.)
Remark 5.6. We remark that the same proof shows that when
$\widetilde {G}={\mathrm {GU}}_n(q)$
with
$q\equiv 1\pmod 4$
and
$\widetilde {B}=\mathcal {E}_2(\widetilde {G}, \widetilde {s})$
is a
$2$
-block of
$\widetilde {G}$
with
$\mathbf { C}_{\widetilde {G}^{\ast }}(\widetilde {s})=\prod {\mathrm {GL}}^\eta _{m_i}(q^{d_i})$
with
$q^{d_i}\equiv -\eta \pmod 4$
for each i, then Conjecture A holds for
$\widetilde {B}$
.
Further, using the description of Sylow
$2$
-subgroups of
${\mathrm {Sp}}_{2n}(q)$
,
${\mathrm {SO}}_{2n+1}(q)$
,
$O_{2n+1}(q)$
,
${\mathrm {SO}}_{2n}^\pm (q)$
, and
$O_{2n}^\pm (q)$
in [Reference Carter and Fong5] and arguing similarly to before, we see that each of these groups also satisfy
$\exp (P/P')\leq 2$
for a Sylow
$2$
subgroup P. So, taking G to be a classical-type group
$\operatorname {CSp}_{2n}(q)$
,
${\mathrm {SO}}_{2n+1}(q)$
, or
$\operatorname {CSO}_{2n}^\pm (q)$
and a block B such that
$B=\mathcal {E}_2(G, s)$
(again applying [Reference Cabanes and Enguehard4, Theorems 9.12 and 21.14]), we may obtain analogous examples using [Reference Fong and Srinivasan10] in place of [Reference Fong and Srinivasan9]. This could be further extended to classical types whose center is disconnected in the cases that each
$\chi \in {\mathrm {Irr}}(B)$
lies in a series
$\mathcal {E}(G, st),$
where
$\mathbf {C}_{{\mathbf {G}}^{\ast }}(st)$
is connected, using [Reference Schaeffer Fry, Taylor and Vinroot31] in place of [Reference Srinivasan and Vinroot32].
6. Primitive characters of prime degree
This section handles the primitivity case of Theorem D. We begin with an easy observation.
Lemma 6.1. Let p be a prime, G a finite group,
$P\in {\mathrm {Syl}}_p(G)$
, and
$\chi \in {\mathrm {Irr}}_{p'}(G)$
with
${\mathbf {lev}}(\chi )\geq 2$
. To prove Conjecture B, it suffices to show that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)$
and, additionally,
${\mathbb Q}_4\subseteq {\mathbb Q}(\chi _P)$
if
$p=2$
.
Proof. Let
$a:={\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)\geq 2$
. We aim to show that
${\mathbb Q}_p(\chi _P)={\mathbb Q}_{p^a}$
. First, we have
${\mathbb Q}(\chi _P)\subseteq {\mathbb Q}_{p^a}$
(see [Reference Navarro and Tiep28, Lemma 7.1]). If p is odd then all the subfields of
${\mathbb Q}_{p^a}$
containing
${\mathbb Q}_p$
are of the form
${\mathbb Q}_{p^b}$
for
$1\leq b\leq a$
(see the proof of [Reference Navarro and Tiep28, Theorem 2.3]), and, therefore, the fact that
${\mathbf {lev}}(\chi _P)=a$
forces
${\mathbb Q}_p(\chi _P)$
to be the entire
${\mathbb Q}_{p^a}$
.
Let
$p=2$
and assume that
${\mathbb Q}_4\subseteq {\mathbb Q}(\chi _P)$
. Now all the subfields of
${\mathbb Q}_{2^a}$
containing
${\mathbb Q}_4$
are again of the form
${\mathbb Q}_{2^b}$
for
$1\leq b\leq a$
, and we still have
${\mathbb Q}_{2^a}={\mathbb Q}(\chi _P)$
.
Lemma 6.2. Let
$K\trianglelefteq \, G$
and
$\overline {\chi }\in {\mathrm {Irr}}(G/K)$
. Let
$\chi $
be the inflation of
$\overline {\chi }$
up to G. Let
$P\in {\mathrm {Syl}}_p(G)$
and
$\overline {P}:=PK/K\in {\mathrm {Syl}}_p(G/K)$
. Then,
$$\begin{align*}{\mathbf{lev}}(\chi)={\mathbf{lev}}(\overline{\chi}) \text{ and } {\mathbf{lev}}(\chi_P)={\mathbf{lev}}(\overline{\chi}_{\overline{P}}). \end{align*}$$
Proof. This follows from the fact that the sets of values of
$\chi $
and
$\overline {\chi }$
, as well as those of
$\chi _P$
and
$\overline {\chi }_{\overline {P}}$
, are the same.
Lemma 6.3. Let
$K_1,...,K_n$
be finite abelian extensions of
${\mathbb Q}$
. Let
$K:=K_1\cdots K_n$
denote the smallest subfield of
${\mathbb C}$
containing all
$K_i$
. Then, K is also a finite abelian extension of
${\mathbb Q}$
and
$$\begin{align*}{\mathbf{lev}}(K)=\max\{{\mathbf{lev}}(K_i):1\leq i\leq n\}. \end{align*}$$
Proof. It is easy to see that
$K\subseteq {\mathbb Q}_{{\mathrm {lcm}}(c(K_1),...,c(K_n))}$
, so K is a finite abelian extension of
${\mathbb Q}$
.
Suppose
$a:=\max \{{\mathbf {lev}}(K_i):1\leq i\leq n\}$
. Then,
$K_i\subseteq {\mathbb Q}_{p^a}{\mathbb Q}_{c(K_i)_{p'}}$
and thus
$K\subseteq {\mathbb Q}_{p^a}{\mathbb Q}_{\prod _i c(K_i)_{p'}}$
, implying that
${\mathbf {lev}}(K)\leq a$
. The lemma follows as it is clear that
${\mathbf {lev}}(K_i)\leq {\mathbf {lev}}(K)$
for every i.
For the remainder of this section, a finite group G is called almost quasisimple if there exists a nonabelian simple group S such that
$S\trianglelefteq \, G/{\mathbf {Z}}(G) \leq {\mathrm {Aut}}(S)$
.
We shall need the following rather technical result, extracted from [Reference Hung, Tiep and Zalesski17].
Lemma 6.4. Let G be an almost quasisimple irreducible primitive subgroup of
${\mathrm {GL}}(r,{\mathbb C})$
, where r is a prime, and
$\chi \in {\mathrm {Irr}}(G)$
the corresponding character. Let S be the socle of
$G/{\mathbf {Z}}(G)$
and M the last term in the derived series of G. Let
$\pi $
be the set of prime divisors of
$r|{\mathbf {Z}}(M)|$
and
$Z_\pi $
denotes the Hall
$\pi $
-subgroup of (the abelian group)
$Z:={\mathbf {Z}}(G)$
. Let
$N:=Z_\pi M$
. Then, the following hold.
-
(i) M is quasisimple with
$M/{\mathbf {Z}}(M)=S$
and
$\chi _M$
is irreducible. -
(ii)
$\varphi :=\chi _N\in {\mathrm {Irr}}(N)$
and
$\varphi $
has the canonical extension
$\widehat {\varphi }$
to G, in the sense of [Reference Navarro25, Corollary 6.2]. Furthermore,
$\chi =\widehat {\varphi }\lambda $
for some linear character
$\lambda $
of
$G/N$
. -
(iii)
${\mathbb Q}(\chi )={\mathbb Q}(\chi _M){\mathbb Q}(\mu ){\mathbb Q}(\lambda ),$
where
$\lambda $
is as in (ii) and
$\mu $
is the irreducible (linear) character of
$Z_\pi $
lying under
$\chi $
.
Proof. This follows from [Reference Hung, Tiep and Zalesski17, Proposition 3.5 and Corollary 4.4] and their proofs.
Theorem 6.5. Let p be a prime and G a finite group. Let
$\chi $
be an irreducible primitive character of G of prime degree not equal to p. Suppose
${\mathbf {lev}}(\chi )\geq 2$
. Then,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{P})$
for
$P\in {\mathrm {Syl}}_p(G)$
. Furthermore, if
$p=2$
then
${\mathbb Q}_4\subseteq {\mathbb Q}(\chi _P)$
.
Proof. We may assume that
$\chi $
is faithful, by modding out by its kernel and using Lemma 6.2 if necessary. Let
$$\begin{align*}r:=\chi(1).\end{align*}$$
Then, G is an irreducible primitive subgroup of
${\mathrm {GL}}(r,{\mathbb C})$
. By [Reference Hung, Tiep and Zalesski17, Lemma 4.1], we are in one of the following situations.
-
(A) G is almost quasisimple.
-
(B) G contains a normal r-subgroup
$R ={\mathbf {Z}}(R)E$
, where E is an irreducible extraspecial r-group of order
$r^{3}$
, and either
$R = E$
or
${\mathbf {Z}}(R)\cong C_4$
.
A. Consider the case, when G is almost quasisimple. As in Lemma 6.4, we use Z for the center of G, S for the socle of
$G/Z$
, and M the last term in the derived series of G. Also,
$\pi $
is the set of prime divisors of
$r|{\mathbf {Z}}(M)|$
and
$Z_\pi $
denotes the Hall
$\pi $
-subgroup of Z. Set
$N:=Z_\pi M$
.
By Lemmas 6.3 and 6.4, we have
$$\begin{align*}{\mathbf{lev}}(\chi)=\max\{{\mathbf{lev}}(\chi_M),{\mathbf{lev}}(\mu),{\mathbf{lev}}(\lambda)\} \end{align*}$$
for some linear characters
$\mu $
of
$Z_\pi $
and
$\lambda $
of
$G/N$
.
(i) Suppose first that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _M)$
. Recall that M is quasisimple and
$\chi _M\in {\mathrm {Irr}}(M)$
, by Lemma 6.4(i). Using Theorem 5.1, we obtain
$$\begin{align*}{\mathbf{lev}}(\chi_M)={\mathbf{lev}}(\chi_Q), \end{align*}$$
for every
$Q\in {\mathrm {Syl}}_p(M)$
. Choosing such a Q that is contained in P, we have
$$\begin{align*}{\mathbf{lev}}(\chi)\geq{\mathbf{lev}}(\chi_P)\geq {\mathbf{lev}}(\chi_Q)={\mathbf{lev}}(\chi_M)={\mathbf{lev}}(\chi), \end{align*}$$
and the first statement of the theorem follows. When
$p=2$
, we know from [Reference Navarro and Tiep28, Theorem A3] that
${\mathbb Q}(\chi _Q)={\mathbb Q}_{2^{{\mathbf {lev}}(\chi _M)}}\supseteq {\mathbb Q}_4$
, and thus
${\mathbb Q}(\chi _P)\supseteq {\mathbb Q}_4$
, as wanted.
(ii) Next, suppose that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\mu )$
. Let
$Q\in {\mathrm {Syl}}_p(Z_\pi )$
. Recall that
$\mu \in {\mathrm {Irr}}(Z_\pi )$
lies under
$\chi $
and
$Z_\pi $
is central in G. Hence,
$\chi _{Z_\pi }$
is a rational multiple of
$\mu $
, and we deduce that
$\chi _Q$
is a rational multiple of
$\mu _Q$
as well. Since
${\mathbf {lev}}(\chi )\geq 2$
, we have
${\mathbb Q}(\chi _Q)= {\mathbb Q}(\mu _Q)\supseteq {\mathbb Q}_4$
, so it remains to show that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)$
.
Observe that
$$\begin{align*}{\mathbf{lev}}(\chi_Q)={\mathbf{lev}}(\mu_Q). \end{align*}$$
Clearly,
${\mathbf {lev}}(\mu )={\mathbf {lev}}(\mu _Q)$
, as
$\mu $
is linear. Altogether, we have
$$\begin{align*}{\mathbf{lev}}(\chi)\geq{\mathbf{lev}}(\chi_Q)={\mathbf{lev}}(\mu_Q)={\mathbf{lev}}(\mu)={\mathbf{lev}}(\chi), \end{align*}$$
implying that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _Q)$
, and we are done again.
(iii) Finally, suppose that
$a={\mathbf {lev}}(\chi )={\mathbf {lev}}(\lambda )>\max \{{\mathbf {lev}}(\chi _M),{\mathbf {lev}}(\mu )\}$
. Notice that N is a central product of
$Z_\pi $
and M and
$\varphi \in {\mathrm {Irr}}(N)$
lies over
$\varphi _M\in {\mathrm {Irr}}(M)$
and
$\mu \in {\mathrm {Irr}}(Z_\pi )$
. Therefore,
$$\begin{align*}{\mathbb Q}(\varphi)={\mathbb Q}(\chi_M){\mathbb Q}(\mu).\end{align*}$$
It follows from Lemma 6.3 that
$$\begin{align*}{\mathbf{lev}}(\varphi)= \max\{{\mathbf{lev}}(\chi_M),{\mathbf{lev}}(\mu)\}<a. \end{align*}$$
As
${\mathbb Q}(\widehat {\varphi })={\mathbb Q}(\varphi )$
(see [Reference Navarro25, Corollary 6.4]), we then have
${\mathbf {lev}}(\widehat {\varphi })<a$
.
Again, by Lemma 6.4,
$\chi =\widehat {\varphi }\lambda $
. So
$\chi _P=\widehat {\varphi }_P\lambda _P$
. Assume to the contrary that
${\mathbf {lev}}(\chi _P)\leq a-1$
. Then, for every
$g\in P$
, we have
$\widehat {\varphi }(g)\neq 0$
and
$$\begin{align*}{\mathbf{lev}}(\lambda(g))={\mathbf{lev}}(\chi(g)\widehat{\varphi}(g)^{-1})\leq \max\{{\mathbf{lev}}(\chi(g)),{\mathbf{lev}}(\widehat{\varphi})\}\leq a-1, \end{align*}$$
which implies that
${\mathbf {lev}}(\lambda )={\mathbf {lev}}(\lambda _P)\leq a-1$
, a contradiction. We have proved that
${\mathbf {lev}}(\chi _P)\geq a$
, which forces
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)$
, as desired.
Now suppose that
$p=2$
. If either
${\mathbf {lev}}(\chi _M)\geq 2$
or
${\mathbf {lev}}(\mu )\geq 2$
then it was already known from parts (i) and (ii) that
${\mathbb Q}_4\subseteq {\mathbb Q}(\chi _P)$
. So let us assume that both
$\chi _M$
and
$\mu $
are
$2$
-rational. Both
$\varphi $
and
$\widehat {\varphi }$
are then
$2$
-rational as well, as
${\mathbb Q}(\widehat {\varphi })={\mathbb Q}(\varphi )={\mathbb Q}(\chi _M){\mathbb Q}(\mu )$
. It follows that
$\widehat {\varphi }_P$
is rational-valued. Now we see that
${\mathbb Q}(\chi _P)\supseteq {\mathbb Q}_4$
, using
$\chi _P=\widehat {\varphi }_P\lambda _P$
together with the facts that
$\lambda $
is linear and
${\mathbf {lev}}(\lambda )\geq 2$
.
B. Next we consider the situation in which G contains a normal r-subgroup
$R ={\mathbf {Z}}(R)E$
, where E is an irreducible extraspecial r-group of order
$r^{3}$
, and either
$R = E$
or
${\mathbf {Z}}(R)\cong C_4$
. By the main result of [Reference Isaacs and Navarro20], we may assume that G is non-solvable. Using [Reference Hung, Tiep and Zalesski17, Theorem 6.1], we obtain
$$\begin{align*}{\mathbb Q}(\chi)={\mathbb Q}(\chi_Z)={\mathbb Q}(\exp(2i\pi/a)),\end{align*}$$
where
$Z:={\mathbf {Z}}(G)$
and
$a\in {\mathbb Z}^{+}$
is a certain divisor of
$\exp (Z)$
divisible by r.
Let
$\theta $
be the (unique) irreducible constituent of
$\chi _Z$
, so that
$\chi _Z=\alpha \theta $
for some
$\alpha \in {\mathbb Z}^+$
. Let
$Q\in {\mathrm {Syl}}_p(Z)$
. As
$\theta $
is linear, we then have
$$\begin{align*}{\mathbf{lev}}(\chi)\geq{\mathbf{lev}}(\chi_Q)={\mathbf{lev}}(\theta_Q)={\mathbf{lev}}(\theta)={\mathbf{lev}}(\chi_Z)={\mathbf{lev}}(\chi),\end{align*}$$
which implies that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _P)$
. Also,
${\mathbb Q}(\chi _P)\supseteq {\mathbb Q}(\chi _Q)={\mathbb Q}(\mu _Q)\supseteq {\mathbb Q}_4$
. The proof is complete.
Theorem D now readily follows from Theorems 4.4 and 6.5, and Lemma 6.1.
7. Further discussion
We have seen the connection between Conjecture A and Navarro–Tiep’s Conjecture B. We now discuss another connection, this time with the well-known AMN conjecture. In particular, we shall explain how Conjecture A implies that the conjectural AMN bijection should respect the p-rationality level of the defect-normalizer restrictions.
7.1. Connection with the AMN conjecture
Keep the notation from §2, so that
$|G|=n=p^bm$
with
$(p,m)=1$
and
$\mathcal {G}:=\mathrm {Gal}({\mathbb Q}_n/{\mathbb Q})\cong \mathcal {I}\times \mathcal {K}$
. Recall that
$\mathcal {H}=\mathcal {I}\times \langle \sigma \rangle ,$
where
$\sigma \in \mathcal {K}$
is such that its restriction to
${\mathbb Q}_m$
is the Frobenius automorphism
$\zeta \mapsto \zeta ^p$
. The McKay–Navarro conjecture predicts that, for
$P\in {\mathrm {Syl}}_p(G)$
, there should exist an
$\mathcal {H}$
-equivariant bijection from
${\mathrm {Irr}}_{p'}(G)$
to
${\mathrm {Irr}}_{p'}({\mathbf {N}}_G(P))$
. Such a bijection necessarily preserves the p-rationality level of characters (see [Reference Hung14, §2], for instance).
As noted in §3, the Galois group
$\mathcal {G}$
permutes the p-blocks of G. Let B be a p-block of G and
$\mathcal {H}_B$
be the subgroup of
$\mathcal {H}$
fixing B. Recall that
$\mathcal {I}\leq \mathcal {H}_B$
.
Now let D be a defect group of B and
$b\in \mathrm {\mathrm {Bl}}({\mathbf {N}}_G(D))$
be the Brauer correspondent of B. The group
$\mathcal {H}_B$
then permutes (and preserves the height) the ordinary characters in B and b. The AMN conjecture [Reference Navarro26, Conjecture B] asserts that there exists a bijection
$$\begin{align*}^{*}: {\mathrm {Irr}}_0(B) \rightarrow {\mathrm {Irr}}_0(b)\end{align*}$$
that commutes with the action of
$\mathcal {H}_B$
. That is,
$$\begin{align*}(\chi^\tau)^{\ast}=(\chi^{*})^\tau\end{align*}$$
for every
$\chi \in {\mathrm {Irr}}_0(B)$
and every
$\tau \in \mathcal {H}_B$
.
Let
${\mathbb F}$
be the fixed field in
${\mathbb Q}_n$
of
$\mathcal {H}_B$
. The AMN conjecture then implies that
$$\begin{align*}{\mathbb F}(\chi)={\mathbb F}(\chi^{\ast}) \end{align*}$$
for all
$\chi \in {\mathrm {Irr}}_0(B)$
. As
$\mathcal {I}\leq \mathcal {H}_B$
, we have
${\mathbb F} \subseteq {\mathbb Q}_m$
, and thus
${\mathbf {lev}}({\mathbb F})=0$
. It follows that the conjectural bijection
$^{\ast }$
preserves the p-rationality level:
$$\begin{align*}{\mathbf{lev}}(\chi)={\mathbf{lev}}(\chi^{\ast}).\end{align*}$$
The following is the AMN conjecture with the defect-normalizer restriction incorporated.
Conjecture 7.1. Let p be a prime and G a finite group. Let
$B\in \mathrm {\mathrm {Bl}}(G)$
be a p-block of G with defect group D and
$b\in \mathrm {\mathrm {Bl}}({\mathbf {N}}_G(D))$
be its Brauer correspondent. Let
$\mathcal {H}_B$
be the subgroup of
$\mathcal {H}$
fixing B. Then, there exists an
$\mathcal {H}_B$
-equivariant bijection
$^{*}: {\mathrm {Irr}}_0(B) \rightarrow {\mathrm {Irr}}_0(b)$
such that
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})={\mathbf {lev}}(\chi ^{\ast })$
for every
$\chi \in {\mathrm {Irr}}_0(B)$
of p-rationality level at least 2.
Theorem 7.2. Conjecture 7.1 follows from the AMN conjecture and Conjecture A. Conversely, Conjecture A follows from Conjecture 7.1.
Proof. We keep the above notation. First, the AMN conjecture implies that there exists an
$\mathcal {H}_B$
-equivariant bijection
$^{*}: {\mathrm {Irr}}_0(B) \rightarrow {\mathrm {Irr}}_0(b)$
such that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi ^{\ast })$
. Conjecture A then implies that
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})={\mathbf {lev}}(\chi ^{\ast })$
for all
$\chi \in {\mathrm {Irr}}_0(B)$
of level at least 2.
For the converse statement, let
$\chi $
be a height-zero character in a block B and assume that there exists a bijection
$^{*}: {\mathrm {Irr}}_0(B) \rightarrow {\mathrm {Irr}}_0(b)$
that commutes with the action of
$\mathcal {H}_B$
such that
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})={\mathbf {lev}}(\chi ^{\ast })$
. As mentioned, we then have
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi ^{\ast })$
, and it follows that
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
, as wanted.
Conjecture 7.1 might be compared with the following conjecture of Navarro and Tiep, which combines Conjecture B and the McKay–Navarro conjecture.
Conjecture 7.3 ([Reference Navarro and Tiep28], Condition D).
Let p be a prime, G a finite group, and
$P\in {\mathrm {Syl}}_p(G)$
. Then, there exists an
$\mathcal {H}$
-equivariant bijection
$^{*}: {\mathrm {Irr}}_{p'}(G) \rightarrow {\mathrm {Irr}}_{p'}({\mathbf {N}}_G(P))$
such that
${\mathbb Q}_p(\chi _P)={\mathbb Q}_p(\chi ^{\ast }_P)$
for all
$\chi \in {\mathrm {Irr}}_{p'}(G)$
.
7.2. Consequences of Conjecture A
A character
$\chi $
is termed almost p-rational if its conductor is not divisible by
$p^2$
, or, equivalently,
${\mathbf {lev}}(\chi )\leq 1$
(see [Reference Hung, Malle and Maróti15]).
Consequence 7.4. Let
$\chi $
be a height-zero character of a finite group G and D a defect group of the p-block of G containing
$\chi $
. Assume Conjecture A holds. Then,
$\chi $
is almost p-rational if and only if
$\chi _{{\mathbf {N}}_G(D)}$
is almost p-rational. In particular, when
$p=2$
,
$\chi $
is
$2$
-rational if and only if
$\chi _{{\mathbf {N}}_G(D)}$
is
$2$
-rational.
Proof. It is clear that if
$\chi $
is almost p-rational then so is
$\chi _{{\mathbf {N}}_G(D)}$
. Conversely, if
$\chi $
is not almost p-rational then
${\mathbf {lev}}(\chi )\geq 2$
, and it follows from Conjecture A that
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})\geq 2$
.
Consequence 7.5. Let G be a finite group with abelian Sylow p-subgroups. Assume that Conjecture A holds. Then,
${\mathbf {lev}}(\chi )={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
for every
$\chi \in {\mathrm {Irr}}(G)$
of p-rationality level at least
$2$
and D a defect group of the p-block of G containing
$\chi $
.
Proof. This follows from the solution of the “if” implication of Brauer’s height zero conjecture [Reference Kessar and Malle21].
Consequence 7.6. Let
$\chi $
be an irreducible
$2$
-height zero character of a finite group G. Suppose that
${\mathbb Q}(\chi )={\mathbb Q}(\sqrt {d})$
is a quadratic number field, where
$d\not \equiv 1 (\bmod \, 4)$
is a square-free integer. Assume that Conjecture A holds. Then,
${\mathbb Q}(\chi )={\mathbb Q}(\chi _{{\mathbf {N}}_G(D)})$
, where D a defect group of the p-block of G containing
$\chi $
.
Proof. Note that
$c(\sqrt {d})=4|d|$
when
$d\not \equiv 1 (\bmod 4)$
is a square-free integer. Therefore, by the hypothesis,
${\mathbf {lev}}(\chi )\geq 2$
. By Conjecture A, we then have
${\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})\geq 2$
. In particular,
$\chi _{{\mathbf {N}}_G(D)}$
is not rational, implying that
${\mathbb Q}(\chi )={\mathbb Q}(\chi _{{\mathbf {N}}_G(D)})$
.
7.3. Examples
We end with examples to justify some of our claims from §1.
First, for height-zero characters
$\chi $
in general,
$\mathbf {lev}(\chi )$
does not always equal
${\mathbf {lev}}(\chi _{D})$
, where D is a defect group of the p-block containing
$\chi $
. For example, when
$p=2$
, the group
$\texttt {SmallGroup}(24,4)$
has characters of degree 2 with
${\mathbf {lev}}(\chi )=2$
and
${\mathbf {lev}}(\chi _D)=0$
; the group SmallGroup(48,5) has characters of degree 2 with
${\mathbf {lev}}(\chi )=3$
and
${\mathbf {lev}}(\chi _D)=2$
; and several similar examples can be found among the SmallGroup library in [11]. There are also examples for odd primes: when
$p=3$
, the group SmallGroup(108,19) has characters of degree 3 with
${\mathbf {lev}}(\chi )=2$
and
${\mathbf {lev}}(\chi _D)=1$
.
Next, the assumption
${\mathbf {lev}}(\chi )\geq 2$
in Conjecture A is necessary. For example, the group
$2.{\textsf {A}}_{10}.2$
with
$p=5$
has characters with degree
$432$
with
${\mathbf {lev}}(\chi )=1$
but
${\mathbf {lev}}(\chi _P)=0={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(P)})$
. Further,
$2.\textsf {A}_{11}$
with
$p=3$
has characters of degree 1584 in blocks having non-maximal defect with
${\mathbf {lev}}(\chi )=1$
and
${\mathbf {lev}}(\chi _D)=0={\mathbf {lev}}(\chi _{{\mathbf {N}}_G(D)})$
.
Acknowledgement
The authors are grateful to Thomas Breuer, Gabriel Navarro, and Benjamin Sambale for several helpful conversations on topics related to this work. Part of this work was completed while the first author was visiting the Department of Mathematics at the University of Denver. He thanks the department and faculty members Alvaro Arias, Mandi Schaeffer Fry, Michael Kinyon, and Petr Vojtechovsky for their hospitality.
The first author gratefully acknowledges the support of the AMS-Simons Research Enhancement Grant (AWD-000167 AMS) and the UA Faculty Research Grant (FRG 1747). The second author gratefully acknowledges support from the National Science Foundation, Award No. DMS-2100912, and her former institution, Metropolitan State University of Denver, which held the award and allowed her to serve as PI. The authors are grateful to the anonymous referee for several helpful comments.
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