1. Introduction
Let
$p$
be a prime number, let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
, and let
$\Gamma _F$
be the absolute Galois group of
$F$
. The norm-residue isomorphism theorem of Voevodsky and Rost [Reference Haesemeyer and WeibelHW19] gives an explicit presentation by generators and relations of the cohomology ring
$H^{* }(F,\mathbb Z/p\mathbb Z)=H^{* }(\Gamma _F,\mathbb Z/p\mathbb Z)$
. In view of this complete description of the cup product, the research on
$H^{* }(F, \mathbb Z/p\mathbb Z)$
shifted in recent years to external operations, defined in terms of the differential graded ring of continuous cochains
$C^{*}(\Gamma _F, \mathbb Z/p\mathbb Z)$
.
Hopkins and Wickelgren [Reference Hopkins and WickelgrenHW15] asked whether
$C^{*}(\Gamma _F, \mathbb Z/p\mathbb Z)$
is formal for every field
$F$
and every prime
$p$
. Loosely speaking, this amounts to saying that no essential information is lost when passing from
$C^{*}(\Gamma _F, \mathbb Z/p\mathbb Z)$
to
$H^{* }(F, \mathbb Z/p\mathbb Z)$
. The authors of [Reference Hopkins and WickelgrenHW15] were unaware of earlier work of Positselski, who had already shown in [Reference PositselskiPos11, Section 9.11] that
$C^{*}(\Gamma _F, \mathbb Z/p\mathbb Z)$
is not formal for some finite extensions
$F$
of
$\mathbb Q_{\ell }$
and
${\mathbb F}_{\ell }((z))$
, where
$\ell \neq p$
. Positselski then wrote a detailed exposition of his counterexamples in [Reference PositselskiPos17].
For Positselski’s method to work, it seemed important that
$F$
did not contain all the roots of unity of
$p$
-power order. This motivated the following question; see [Reference PositselskiPos17, p. 226].
Question 1.1 (Positselski). Does there exist a field
$F$
containing all roots of unity of
$p$
-power order such that
$C^{*}(\Gamma _F,\mathbb Z/p\mathbb Z)$
is not formal?
We showed in [Reference Merkurjev and ScaviaMS22, Theorem 1.6] that Question 1.1 has a positive answer when
$p=2$
. In the present work, we provide examples showing that the answer to Question 1.1 is affirmative for all primes
$p$
.
Theorem 1.2.
Let
$p$
be a prime number and let
$F$
be a field of characteristic different from
$p$
. There exists a field
$L$
containing
$F$
such that the differential graded ring
$C^{*}(\Gamma _L,\mathbb Z/p\mathbb Z)$
is not formal.
To detect non-formality of the cochain differential graded ring, we use Massey products. For any
$n\geq 2$
and all
$\chi _1,\ldots ,\chi _n\in H^1(F,\mathbb Z/p\mathbb Z)$
, the Massey product of
$\chi _1,\ldots ,\chi _n$
is a certain subset
$\langle {\chi _1,\ldots ,\chi _n}\rangle \subset H^2(F,\mathbb Z/p\mathbb Z)$
; see Section 2.2 for the definition. We say that
$\langle {\chi _1,\ldots ,\chi _n}\rangle$
is defined if it is not empty, and that it vanishes if it contains
$0$
. When
$\operatorname {char}(F)\neq p$
and
$F$
contains a primitive
$p$
th root of unity
$\zeta$
, Kummer theory gives an identification
$H^1(F,\mathbb Z/p\mathbb Z)=F^{\times }/F^{\times p}$
, and we may thus consider Massey products
$\langle {a_1,\ldots ,a_n}\rangle$
, where
$a_i\in F^\times$
for
$1\leq i\leq n$
.
Let
$n\geq 3$
be an integer, let
$\chi _1,\ldots ,\chi _n\in H^1(F,\mathbb Z/p\mathbb Z)$
and consider the following assertions.
$$\begin{align}\textrm{The Massey product $\langle {\chi _1,\ldots ,\chi _n}\rangle $ vanishes.}\end{align}$$
$$\begin{align}\textrm {The Massey product $\langle {\chi _1,\ldots ,\chi _n}\rangle $ is defined.}\end{align}$$
$$\begin{align}\textrm {We have $\chi _i\cup \chi _{i+1}=0$ for all $1\leq i\leq n-1$.}\end{align}$$
We have that (1.1) implies (1.2), and that (1.2) implies (1.3). The Massey vanishing conjecture, due to Mináč and Tân [Reference Mináč and TânMT17b] and inspired by the earlier work of Hopkins and Wickelgren [Reference Hopkins and WickelgrenHW15], predicts that (1.2) implies (1.1). This conjecture has sparked a lot of activity in recent years. When
$F$
is an arbitrary field, the conjecture was shown when either
$n=3$
and
$p$
is arbitrary, by Efrat and Matzri and Mináč and Tân [Reference MatzriMat18, Reference Efrat and MatzriEM17, Reference Mináč and TânMT16], or when
$n=4$
and
$p=2$
, by [Reference Merkurjev and ScaviaMS23]. When
$F$
is a number field, the conjecture was proved for all
$n\geq 3$
and all primes
$p$
by Harpaz and Wittenberg [Reference Harpaz and WittenbergHW23].
When
$n=3$
, it is a direct consequence of the definition of the Massey product that (1.3) implies (1.2). Thus, (1.1), (1.2) and (1.3) are equivalent when
$n=3$
.
In [Reference Mináč and TânMT17a, Question 4.2], Mináč and Tân asked whether (1.3) implies (1.1). This became known as the strong Massey vanishing conjecture (see, e.g., [Reference Pál and SzabóPS18]). If
$F$
is a field,
$p$
is a prime number and
$n\geq 3$
is an integer, then, for all characters
$\chi _1,\ldots ,\chi _n\in H^1(F,\mathbb Z/p\mathbb Z)$
such that
$\chi _i\cup \chi _{i+1}=0$
for all
$1\leq i\leq n-1$
, the Massey product
$\langle {\chi _1,\ldots ,\chi _n}\rangle$
vanishes.
The strong Massey vanishing conjecture implies the Massey vanishing conjecture. However, Harpaz and Wittenberg produced a counterexample to the strong Massey vanishing conjecture, for
$n=4$
,
$p=2$
and
$F=\mathbb Q$
; see [Reference Guillot, Mináč and TopazGMT18, Example A.15]. More precisely, if we let
$b=2$
,
$c=17$
and
$a=d=bc=34$
, then
$(a,b)=(b,c)=(c,d)=0$
in
$\operatorname {Br}(\mathbb Q)$
but
$\langle {a,b,c,d}\rangle$
is not defined over
$\mathbb Q$
. In this example, the classes of
$a,b,c,d$
in
$F^{\times }/F^{\times 2}$
are not
${\mathbb F}_2$
-linearly independent modulo squares. In fact, by a theorem of Guillot, Mináč, Topaz and Wittenberg [Reference Guillot, Mináč and TopazGMT18], if
$F$
is a number field and
$a,b,c,d$
are independent in
$F^\times /F^{\times 2}$
and satisfy
$(a,b)=(b,c)=(c,d)=0$
in
$\operatorname {Br}(F)$
, then
$\langle {a,b,c,d}\rangle$
vanishes.
If
$F$
is a field for which the strong Massey vanishing conjecture fails, for some
$n\geq 3$
and some prime
$p$
, then
$C^{*}(\Gamma _F,\mathbb Z/p\mathbb Z)$
is not formal; see Lemma 2.3. Therefore, Theorem 1.2 follows from the next more precise result.
Theorem 1.3.
Let
$p$
be a prime number and let
$F$
be a field of characteristic different from
$p$
. There exist a field
$L$
containing
$F$
and
$\chi _1,\chi _2,\chi _3,\chi _4\in H^1(L,\mathbb Z/p\mathbb Z)$
such that
$\chi _1\cup \chi _2=\chi _2\cup \chi _3=\chi _3\cup \chi _4=0$
in
$H^2(L,\mathbb Z/p\mathbb Z)$
but
$\langle {\chi _1,\chi _2,\chi _3,\chi _4}\rangle$
is not defined. Thus, the strong Massey vanishing conjecture at
$n=4$
and the prime
$p$
fails for
$L$
, and
$C^{*}(\Gamma _L,\mathbb Z/p\mathbb Z)$
is not formal.
This gives the first counterexamples to the strong Massey vanishing conjecture for all odd primes
$p$
. We easily deduce that (1.3) does not imply (1.2) for all
$n\geq 4$
in general: indeed, if the fourfold Massey product
$\langle {\chi _1,\chi _2,\chi _3,\chi _4}\rangle$
is not defined, neither is the
$n$
-fold Massey product
$\langle {\chi _1,\chi _2,\chi _3,\chi _4,0,\ldots ,0}\rangle$
. Theorem 1.3 was proved in [Reference Merkurjev and ScaviaMS22, Theorem 1.6] when
$p=2$
, and is new when
$p$
is odd. Our proof of Theorem 1.3 is uniform in
$p$
.
We now describe the main ideas that go into the proof of Theorem 1.3. We may assume, without loss of generality, that
$F$
contains a primitive
$p$
th root of unity. In § 2, we collect preliminaries on formality, Massey products and Galois algebras. In particular, we recall Dwyer’s theorem (see Theorem 2.4): a Massey product
$\langle {\chi _1,\ldots ,\chi _n}\rangle \subset H^2(F,\mathbb Z/p\mathbb Z)$
vanishes (respectively, is defined) if and only if the homomorphism
$(\chi _1,\ldots ,\chi _n)\colon \Gamma _F\to (\mathbb Z/p\mathbb Z)^n$
lifts to the group
$U_{n+1}$
of upper unitriangular matrices in
$\operatorname {GL}_{n+1}({\mathbb F}_p)$
(respectively, to the group
$\overline {U}_{n+1}$
of upper unitriangular matrices in
$\operatorname {GL}_{n+1}({\mathbb F}_p)$
with top-right corner removed). As for [Reference Merkurjev and ScaviaMS22, Theorem 1.6], our approach is based on Corollary 2.5, which is a restatement of Theorem 2.4 in terms of Galois algebras.
In § 3, we show that a fourfold Massey product
$\langle {a,b,c,d}\rangle$
is defined over
$F$
if and only if a certain system of equations admits a solution over
$F$
. Moreover, the variety defined by these equations is a torsor under a torus; see Proposition 3.7. This equivalence is proved by using Dwyer’s Theorem 2.4 to rephrase the property that
$\langle {a,b,c,d}\rangle$
is defined in terms of
$\overline {U}_5$
-Galois algebras, and then by a detailed study of Galois
$G$
-algebras, for
$G=U_3,\overline {U}_4,U_4,\overline {U}_5$
. As a consequence, we also obtain an alternative proof of the Massey vanishing conjecture for
$n=3$
and any prime
$p$
; see Proposition 3.6.
In § 4, we use the work of § 3.4 to construct a ‘generic variety’ for the property that
$\langle {a,b,c,d}\rangle$
is defined. More precisely, under the assumption that
$(a,b)=(c,d)=0$
in
$\operatorname {Br}(F)$
and letting
$X$
be the Severi–Brauer variety of
$(b,c)$
, we construct an
$F$
-torus
$T$
and a
$T_{F(X)}$
-torsor
$E_w$
such that, if
$E_w$
is non-trivial, then
$\langle {a,b,c,d}\rangle$
is not defined over
$F(X)$
; see Corollary 4.5. The definition of
$E_w$
depends on a rational function
$w\in F(X)^\times$
, which we construct in Lemma 4.1(3).
Since
$(a,b)=(b,c)=(c,d)=0$
in
$\operatorname {Br}(F(X))$
, the proof of Theorem 1.3 will be complete once we give an example of
$a,b,c,d$
for which the corresponding torsor
$E_w$
is non-trivial. Here, we consider the generic quadruple
$a,b,c,d$
such that
$(a,b)$
and
$(c,d)$
are trivial. More precisely, we let
$x,y$
be two independent variables over
$F$
, and replace
$F$
by
$E:= F(x,y)$
. We then set
$a:= 1-x$
,
$b:= x$
,
$c:= y$
and
$d:= 1-y$
over
$E$
. We have
$(a,b)=(c,d)=0$
in
$\operatorname {Br}(E)$
. The class
$(b,c)$
is not zero in
$\operatorname {Br}(E)$
, so the Severi–Brauer variety
$X/E$
of
$(b,c)$
is non-trivial, but
$(b,c)=0$
over
$L:= E(X)$
.
It is natural to attempt to prove that
$E_w$
is non-trivial over
$L$
by performing residue calculations to deduce that this torsor is ramified. However, the torsor
$E_w$
is in fact unramified. We are thus led to consider a finer obstruction to the triviality of
$E_w$
. This ‘secondary obstruction’ is only defined for unramified torsors. We describe the necessary homological algebra in Appendix A, and we define the obstruction and give a method to compute it in Appendix B. In § 5, an explicit calculation shows that the obstruction is non-zero on
$E_w$
, and hence
$E_w$
is non-trivial, as desired.
1.1 Notation
Let
$F$
be a field, let
$F_s$
be a separable closure of
$F$
and denote by
$\Gamma _F:= \operatorname {Gal}(F_s/F)$
the absolute Galois group of
$F$
.
If
$E$
is an
$F$
-algebra, we let
$H^i(E,-)$
be the étale cohomology of
$\operatorname {Spec}(E)$
(possibly non-abelian if
$i\leq 1$
). If
$E$
is a field,
$H^i(E,-)$
may be identified with the continuous cohomology of
$\Gamma _E$
.
We fix a prime
$p$
, and we suppose that
$\operatorname {char}(F)\neq p$
. If
$E$
is an
$F$
-algebra and
$a_1,\ldots ,a_n\in E^{\times }$
, we define the étale
$E$
-algebra
$E_{a_1,\ldots ,a_n}$
by
\begin{equation*}E_{a_1,\ldots ,a_n}:= E[x_1,\ldots ,x_n]/(x_1^p-a_1,\ldots ,x_n^p-a_n),\end{equation*}
and we set
$(a_i)^{1/p}:= x_i$
. More generally, for all integers
$d$
, we set
$(a_i)^{d/p}:= x_i^d$
. We denote by
$R_{a_1,\ldots ,a_n}(-)$
the functor of Weil restriction along
$F_{a_1,\ldots ,a_n}/F$
. In particular,
$R_{a_1,\ldots ,a_n}({\mathbb G}_{\operatorname {m}})$
is the quasi-trivial torus associated to
$F_{a_1,\ldots ,a_n}/F$
, and we denote by
$R^{(1)}_{a_1,\ldots ,a_n}({\mathbb G}_{\operatorname {m}})$
the norm-one subtorus of
$R_{a_1,\ldots ,a_n}({\mathbb G}_{\operatorname {m}})$
. We denote by
$N_{a_1,\ldots ,a_n}$
the norm map from
$F_{a_1,\ldots ,a_n}$
to
$F$
.
We write
$\operatorname {Br}(F)$
for the Brauer group of
$F$
. If
$\operatorname {char}(F)\neq p$
and
$F$
contains a primitive
$p$
th root of unity, for all
$a,b\in F^\times$
we denote by
$(a,b)$
the corresponding degree-
$p$
cyclic algebra and also its class in
$\operatorname {Br}(F)$
; see § 2.1. We denote by
$N_{a_1,\ldots ,a_n}\colon \operatorname {Br}(F_{a_1,\ldots ,a_n})\to \operatorname {Br}(F)$
the corestriction map along
$F_{a_1,\ldots ,a_n}/F$
.
An
$F$
-variety is a separated integral
$F$
-scheme of finite type. If
$X$
is an
$F$
-variety, we let
$F(X)$
be the function field of
$X$
, and we write
$X^{(1)}$
for the collection of all points of codimension
$1$
in
$X$
. We set
$X_s:= X\times _FF_s$
. If
$K$
is an étale algebra over
$F$
, we write
$X_K$
for
$X\times _FK$
. For all
$a_1,\ldots ,a_n\in F^\times$
, we write
$X_{a_1,\ldots ,a_n}$
for
$X_{F_{a_1,\ldots ,a_n}}$
. When
$X=\mathbb P^d_F$
is a
$d$
-dimensional projective space, we denote by
$\mathbb P^d_{a_1,\ldots ,a_n}$
the base change of
$\mathbb P^d_F$
to
$F_{a_1,\ldots ,a_d}$
.
2. Preliminaries
2.1 Galois algebras and Kummer theory
Let
$F$
be a field and let
$G$
be a finite group. A
$G$
-algebra is an étale
$F$
-algebra
$L$
on which
$G$
acts via
$F$
-algebra automorphisms. The
$G$
-algebra
$L$
is Galois if
$|G|={\dim }_F(L)$
and
$L^G=F$
; see [Reference Knus, Merkurjev, Rost, Tignol and TitsKMRT98, Definitions (18.15)]. A
$G$
-algebra
$L/F$
is Galois if and only if the morphism of schemes
$\operatorname {Spec}(L)\to \operatorname {Spec}(F)$
is an étale
$G$
-torsor. If
$L/F$
is a Galois
$G$
-algebra, then the group algebra
$\mathbb Z[G]$
acts on the multiplicative group
$L^{\times }$
: an element
${{\sum }}_{i=1}^r m_ig_i\in \mathbb Z[G]$
, where
$m_i\in \mathbb Z$
and
$g_i\in G$
, sends
$x\in L^{\times }$
to
${{\prod }}_{i=1}^r g_i(x)^{m_i}$
.
By [Reference Knus, Merkurjev, Rost, Tignol and TitsKMRT98, Example (28.15)], we have a canonical bijection
\begin{align} \operatorname {Hom}_{\operatorname {cont}}(\Gamma _F,G)/_{\sim }\xrightarrow {\sim }\left \{\text {Isomorphism classes of Galois}\,\,G\text{-algebras over}\,\,F\right \}, \end{align}
where, if
$f_1,f_2\colon \Gamma _F\to G$
are continuous group homomorphisms, we say that
$f_1\sim f_2$
if there exists
$g\in G$
such that
$gf_1(\sigma )g^{-1}=f_2(\sigma )$
for all
$\sigma \in \Gamma _F$
.
Let
$H$
be a normal subgroup of
$G$
. Under the correspondence (2.1), the map
$\operatorname {Hom}_{\operatorname {cont}}(\Gamma _F,G)/_{\sim }\to \operatorname {Hom}_{\operatorname {cont}}(\Gamma _F,G/H)/_{\sim }$
sends the class of a Galois
$G$
-algebra
$L$
to the class of the Galois
$G/H$
-algebra
$L^H$
.
Lemma 2.1.
Let
$G$
be a finite group, and let
$H, H', S$
be normal subgroups of
$G$
such that
$H\subset S$
,
$H'\subset S$
, and the following square is cartesian.
-
(1) Let
$L$
be a Galois
$G$
-algebra. Then
$L^H \otimes _{L^S} L^{H'}$
has a Galois
$G$
-algebra structure given by
$g(x\otimes x'):= g(x)\otimes g(x')$
for all
$x\in L^H$
and
$x'\in L^{H'}$
, and the inclusions
$L^H\to L$
and
$L^{H'}\to L$
induce an isomorphism of Galois
$G$
-algebras
$L^H \otimes _{L^S} L^{H'} \rightarrow L$
.
-
(2) Conversely, let
$K$
be a Galois
$G/H$
-algebra, let
$K'$
be a Galois
$G/H'$
-algebra and let
$E$
be a Galois
$G/S$
-algebra. Suppose we are given
$G$
-equivariant algebra homomorphisms
$E \rightarrow K$
and
$E \rightarrow K'$
. Endow the tensor product
$L := K \otimes _{E} K'$
with the structure of a
$G$
-algebra given by
$g(x\otimes x'):= g(x)\otimes g(x')$
for all
$x\in K$
and
$x'\in K'$
. Then
$L$
is a Galois
$G$
-algebra such that
$L^H\simeq K$
as
$G/H$
-algebras and
$L^{H'}\simeq K'$
as
$G/H'$
-algebras.
The condition that (2.2) is cartesian is equivalent to
$H\cap H'= \left \{1\right \}$
and
$S=HH'$
.
Proof.
(1) It is clear that the formula
$g(x\otimes x'):= g(x)\otimes g(x')$
makes
$L^H \otimes _{L^S} L^{H'}$
into a
$G$
-algebra. Consider the following commutative square of
$F$
-schemes.
After base change to a separable closure of
$F$
, this square becomes the cartesian square (2.2), and therefore it is cartesian. Passing to coordinate rings, we deduce that the homomorphism
$L^H \otimes _{L^S} L^{H'} \rightarrow L$
is an isomorphism of
$G$
-algebras. In particular, since
$L$
is a Galois
$G$
-algebra, so is
$L^H \otimes _{L^S} L^{H'}$
.
(2) We have the following
$G$
-equivariant cartesian diagram.
Every
$G$
-equivariant morphism between
$G/H$
and
$G/S$
is isomorphic to the projection map
$G/H\to G/S$
. Therefore, the base change of
$\operatorname {Spec}(K) \to \operatorname {Spec}(E)$
to
$F_s$
is
$G$
-equivariantly isomorphic to the projection
$G/H \to G/S$
. Similarly for
$\operatorname {Spec}(K')\to \operatorname {Spec}(E)$
. Therefore, the base change of
$\operatorname {Spec}(L)\to \operatorname {Spec}(F)$
over
$F_s$
is
$G$
-equivariantly isomorphic to
$(G/H)\times _{G/S}(G/H')\simeq G$
, that is, the morphism
$\operatorname {Spec}(L)\to \operatorname {Spec}(F)$
is an étale
$G$
-torsor.
Suppose that
$\operatorname {char}(F)\neq p$
and that
$F$
contains a primitive
$p$
th root of unity. We fix a primitive
$p$
th root of unity
$\zeta \in F^\times$
. This determines an isomorphism of Galois modules
$\mathbb Z/p\mathbb Z \simeq \mu _p$
, given by
$1\mapsto \zeta$
, and so the Kummer sequence yields an isomorphism
\begin{align} \operatorname {Hom}_{\operatorname {cont}}(\Gamma _F,\mathbb Z/p\mathbb Z)=H^1(F,\mathbb Z/p\mathbb Z )\simeq H^1(F,\mu _p)\simeq F^{\times }/F^{\times p}. \end{align}
For every
$a\in F^{\times }$
, we let
$\chi _a\colon \Gamma _F\to \mathbb Z/p\mathbb Z$
be the homomorphism corresponding to the coset
$a F^{\times p}$
under (2.3). Explicitly, letting
$a'\in F_{{s}}^\times$
be such that
$(a')^p=a$
, we have
$g(a')=\zeta ^{\chi _a(g)}a'$
for all
$g\in \Gamma _F$
. This definition does not depend on the choice of
$a'$
.
Now let
$n\geq 1$
be an integer. For all
$i=1,\ldots ,n$
, let
$\sigma _i$
be the canonical generator of the
$i$
th factor
$\mathbb Z/p\mathbb Z$
of
$(\mathbb Z/p\mathbb Z)^n$
. By (2.3), all Galois
$(\mathbb Z/p\mathbb Z)^n$
-algebras over
$F$
are of the form
$F_{a_1,\ldots ,a_n}$
, where
$a_1,\ldots ,a_n\in F^\times$
and the Galois
$(\mathbb Z/p\mathbb Z)^n$
-algebra structure is defined by
$(\sigma _i-1)a_i^{1/p}=\zeta$
for all
$i$
and by
$(\sigma _i-1)a_j^{1/p}=1$
for all
$j\neq i$
.
We write
$(a,b)$
for the cyclic degree-
$p$
central simple algebra over
$F$
generated, as an
$F$
-algebra, by
$F_a$
and an element
$y$
such that
\begin{equation*}y^p=b,\!\quad ty=y\sigma _a(t)\quad \text {for all $t\in F_a$}.\end{equation*}
We also write
$(a,b)$
for the class of
$(a,b)$
in
$\operatorname {Br}(F)$
. The Kummer sequence yields a group isomorphism
\begin{equation*}\iota \colon H^2(F,\mathbb Z/p\mathbb Z)\xrightarrow {\sim }\operatorname {Br}(F)[p].\end{equation*}
For all
$a,b\in F^{\times }$
, we have
$\iota (\chi _a\cup \chi _b)=(a,b)$
in
$\operatorname {Br}(F)$
; see [Reference Serre and GreenbergSer79, Chapter XIV, Proposition 5].
Lemma 2.2.
Let
$p$
be a prime, and let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
. The following are equivalent.
-
(i) We have
$(a,b)=0$
in
$\operatorname {Br}(F)$
. -
(ii) There exists
$\alpha \in F_a^\times$
such that
$b=N_a(\alpha )$
. -
(iii) There exists
$\beta \in F_b^\times$
such that
$a=N_b(\beta )$
.
Proof. See [Reference Serre and GreenbergSer79, Chapter XIV, Proposition 4(iii)].
2.2 Formality and Massey products
Let
$(A,\partial )$
be a differential graded ring, that is,
$A=\oplus _{i\geq 0}A^i$
is a non-negatively graded abelian group with an associative multiplication which respects the grading, and
$\partial \colon A\to A$
is a group homomorphism of degree
$1$
such that
$\partial \circ \partial =0$
and
$\partial (ab)=\partial (a)b+(-1)^ia\partial (b)$
for all
$i\geq 0$
,
$a\in A^i$
and
$b\in A$
. We denote by
$H^{* }(A):= \operatorname {Ker}(\partial )/\operatorname {Im}(\partial )$
the cohomology of
$(A,\partial )$
, and we write
$\cup$
for the multiplication (cup product) on
$H^{* }(A)$
.
We say that
$A$
is formal if it is quasi-isomorphic, as a differential graded ring, to
$H^{* }(A)$
with the zero differential.
Let
$n\geq 2$
be an integer and let
$a_1,\ldots ,a_n\in H^1(A)$
. A defining system for the
$n$
th order Massey product
$\langle {a_1,\ldots ,a_n}\rangle$
is a collection
$M$
of elements
$a_{ij}\in A^1$
, where
$1\leq i\lt j\leq n+1$
,
$(i,j)\neq (1,n+1)$
, such that:
-
(1)
$\partial (a_{i,i+1})=0$
and
$a_{i,i+1}$
represents
$a_i$
in
$H^1(A)$
; and -
(2)
$\partial (a_{ij})=-{{\sum }}_{l=i+1}^{j-1}a_{il}a_{lj}$
for all
$i\lt j-1$
.
It follows from (2) that
$-{{\sum }}_{l=2}^na_{1l}a_{l,n+1}$
is a
$2$
-cocycle: we write
$\langle {a_1,\ldots ,a_n}\rangle _M$
for its cohomology class in
$H^2(A)$
, called the value of
$\langle {a_1,\ldots ,a_n}\rangle$
corresponding to
$M$
. By definition, the Massey product of
$a_1,\ldots ,a_n$
is the subset
$\langle {a_1,\ldots ,a_n}\rangle$
of
$H^2(A)$
consisting of the values
$\langle {a_1,\ldots ,a_n}\rangle _M$
of all defining systems
$M$
. We say that the Massey product
$\langle {a_1,\ldots ,a_n}\rangle$
is defined if it is non-empty, and that it vanishes if
$0\in \langle {a_1,\ldots ,a_n}\rangle$
.
Lemma 2.3.
Let
$(A,\partial )$
be a differential graded ring, let
$n\geq 3$
be an integer and let
$\alpha _1,\ldots ,\alpha _n$
be elements of
$H^1(A)$
satisfying
$\alpha _i\cup \alpha _{i+1}=0$
for all
$1\leq i\leq n-1$
. If
$A$
is formal, then
$\langle {\alpha _1,\ldots ,\alpha _n}\rangle$
vanishes.
Proof. See [Reference Pál and QuickPQ22, Theorem 3.8].
2.3 Dwyer’s theorem
Let
$p$
be a prime, and let
$U_{n+1}\subset \operatorname {GL}_{n+1}({\mathbb F}_p)$
be the subgroup of
$(n+1)\times (n+1)$
upper unitriangular matrices. For all
$1\leq i\lt j\leq n+1$
, we denote by
$e_{ij}\in U_{n+1}$
the matrix whose non-diagonal entries are all zero except for the entry
$(i,j)$
, which is equal to
$1$
. We set
$\sigma _i:= e_{i,i+1}$
for all
$1\leq i\leq n$
. By [Reference Biss and DasguptaBD01, Theorem 1], the group
$U_{n+1}$
admits a presentation with generators the
$\sigma _i$
and the following relations:
\begin{align} \sigma _i^p=1\quad \text {for all $1\leq i\leq n$,} \\[-32pt] \nonumber \end{align}
\begin{align} [\sigma _i,\sigma _j]=1\quad \text {for all $1\leq i\leq j-2\leq n-2$,} \\[-24pt] \nonumber \end{align}
\begin{align} [\sigma _i,[\sigma _i,\sigma _{i+1}]]=[\sigma _{i+1},[\sigma _i,\sigma _{i+1}]]=1\quad \text {for all $1\leq i\leq n-2$,} \\[-24pt] \nonumber \end{align}
\begin{align} [[\sigma _i,\sigma _{i+1}],[\sigma _{i+1},\sigma _{i+2}]]=1\quad \text {for all $1\leq i\leq n-3$.} \\[6pt] \nonumber \end{align}
The following relations holds in
$U_{n+1}$
:
\begin{equation*} [e_{ij},e_{jk}]=e_{ik}\quad \text {for all $1\leq i\lt j\lt k\leq n+1$.} \end{equation*}
By induction, we deduce that
\begin{equation*}e_{1,n+1}=[\sigma _1,[\sigma _2,\ldots ,[\sigma _{n-2},[\sigma _{n-1},\sigma _n]]\ldots ]].\end{equation*}
The center
$Z_{n+1}$
of
$U_{n+1}$
is the subgroup generated by
$e_{1,n+1}$
. The factor group
$\overline {U}_{n+1}:= U_{n+1}/Z_{n+1}$
may be identified with the group of all
$(n+1)\times (n+1)$
upper unitriangular matrices with entry
$(1,n+1)$
omitted. For all
$1\leq i\lt j\leq n+1$
, let
$\overline {e}_{ij}$
be the coset of
$e_{ij}$
in
$\overline {U}_{n+1}$
, and set
$\overline {\sigma }_i:= \overline {e}_{i,i+1}$
for all
$1\leq i\leq n$
. Then
$\overline {U}_{n+1}$
is generated by all the
$\overline{\sigma}_i$
modulo the relations
\begin{align} \overline {\sigma }_i^p=1\quad \text {for all $1\leq i\leq n$,} \\[-24pt] \nonumber \end{align}
\begin{align} [\overline {\sigma }_i,\overline {\sigma }_j]=1\quad \text {for all $1\leq i\leq j-2\leq n-2$,} \\[-24pt] \nonumber \end{align}
\begin{align} [\overline {\sigma }_i,[\overline {\sigma }_i,\overline {\sigma }_{i+1}]=[\overline {\sigma }_{i+1},[\overline {\sigma }_i,\overline {\sigma }_{i+1}]]=1\quad \text {for all $1\leq i\leq n-2$,} \\[-24pt] \nonumber \end{align}
\begin{align} [[\overline {\sigma }_i,\overline {\sigma }_{i+1}],[\overline {\sigma }_{i+1},\overline {\sigma }_{i+2}]]=1\quad \text {for all $1\leq i\leq n-3$,} \\[-24pt] \nonumber \end{align}
\begin{align} [\overline {\sigma }_1,[\overline {\sigma }_2,\ldots ,[\overline {\sigma }_{n-2},[\overline {\sigma }_{n-1},\overline {\sigma }_n]]\ldots ]]=1. \end{align}
We write
$u_{ij}\colon U_{n+1}\to \mathbb Z/p\mathbb Z$
for the
$(i,j)$
th coordinate function on
$U_{n+1}$
. Note that
$u_{ij}$
is not a group homomorphism unless
$j=i+1$
. We have a commutative diagram
where the row is a central exact sequence and the homomorphism
$U_{n+1}\to (\mathbb Z/p\mathbb Z)^n$
is given by
$(u_{12},u_{23},\ldots , u_{n,n+1})$
. We also let
\begin{equation*}Q_{n+1}:= \operatorname {Ker}[U_{n+1}\to (\mathbb Z/p\mathbb Z)^n],\quad \overline {Q}_{n+1}:= \operatorname {Ker}[\overline {U}_{n+1}\to (\mathbb Z/p\mathbb Z)^n]=Q_{n+1}/Z_{n+1}.\end{equation*}
Note that
$Z_{n+1}\subset Q_{n+1}$
, with equality when
$n=2$
.
Let
$G$
be a profinite group. The complex
$(C^{*}(G,\mathbb Z/p\mathbb Z),\partial )$
of mod
$p$
non-homogeneous continuous cochains of
$G$
with the standard cup product is a differential graded ring. Therefore,
$H^{* }(G,\mathbb Z/p\mathbb Z)=H^{* }(C^{*}(G,\mathbb Z/p\mathbb Z),\partial )$
is endowed with Massey products. The following theorem is due to Dwyer [Reference DwyerDwy75].
Theorem 2.4 (Dwyer). Let
$p$
be a prime number, let
$G$
be a profinite group, let
$\chi _1,\ldots ,\chi _n\in H^1(G,\mathbb Z/p\mathbb Z)$
and write
$\chi \colon G\to (\mathbb Z/p\mathbb Z)^n$
for the continuous homomorphism with components
$(\chi _1,\ldots ,\chi _n)$
. Consider diagram (
2.13
).
-
(1) The Massey product
$\langle {\chi _1,\ldots ,\chi _n}\rangle$
is defined if and only if
$\chi$
lifts to a continuous homomorphism
$G\to \overline {U}_{n+1}$
. -
(2) The Massey product
$\langle {\chi _1,\ldots ,\chi _n}\rangle$
vanishes if and only if
$\chi$
lifts to a continuous homomorphism
$G\to U_{n+1}$
.
Proof. See [Reference DwyerDwy75] for Dwyer’s original proof in the setting of abstract groups, and see [Reference EfratEfr14] or [Reference Harpaz and WittenbergHW23, Proposition 2.2] for the statement in the case of profinite groups.
Theorem 2.4 may be rephrased as follows.
Corollary 2.5.
Let
$p$
be a prime, let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
, and let
$a_1,\ldots ,a_n\in F^\times$
. The Massey product
$\langle {a_1,\ldots ,a_n}\rangle \subset H^2(F,\mathbb Z/p\mathbb Z)$
is defined (respectively, vanishes) if and only if there exists a Galois
$\overline {U}_{n+1}$
-algebra
$K/F$
(respectively, a Galois
$U_{n+1}$
-algebra
$L/F$
) such that
$K^{\overline {Q}_{n+1}}\simeq F_{a_1,\ldots ,a_n}$
(respectively,
$L^{{Q}_{n+1}}\simeq F_{a_1,\ldots ,a_n}$
) as
$(\mathbb Z/p\mathbb Z)^n$
-algebras.
We will apply Lemma 2.1 to the cartesian square of groups
where
${\varphi }_{n+1}$
(respectively,
${\varphi }'_{n+1}$
) is the restriction homomorphism from
$U_{n+1}$
or from
$\overline {U}_{n+1}$
to the top-left (respectively, bottom-right)
$n\times n$
subsquare
$U_n$
in
$U_{n+1}$
.
The fact that the square (2.14) is cartesian is proved in [Reference Merkurjev and ScaviaMS22, Proposition 2.7] when
$p=2$
. The proof extends to odd
$p$
without change.
Remark 2.6. The presentations of
$U_{n+1}$
and
$\overline {U}_{n+1}$
of [Reference Biss and DasguptaBD01] given above will allow us to avoid lengthy calculations in § 3, but they are not essential for our arguments. One could instead use the following classical presentations of
$U_{n+1}$
and
$\overline {U}_{n+1}$
, which are reminiscent of the Steinberg relations for the Steinberg group of a ring in algebraic K-theory.
The group
$U_{n+1}$
admits a presentation with generators
$\{e_{ij}:1\leq i\lt j\leq n+1\}$
and the following relations:
\begin{align}e_{ij}^p=1\quad \text {for all $1\leq i\lt j\leq n+1$},\end{align}
\begin{align}[e_{ij},e_{jk}]=e_{ik}\quad \text {for all $1\leq i\lt j\lt k\leq n+1$},\end{align}
\begin{align}[e_{ij},e_{kl}]=1\quad \text {for all $1\leq i\lt j\leq n+1$, $1\leq k\lt l\leq n+1$, $i\neq l$, $j\neq k$}.\end{align}
This is a particular case of [Reference Abramenko and BrownAB08, Proposition 7.108], where we choose
$w$
to be the longest element of the Weyl group of
$\operatorname {GL}_{n+1}$
over
${\mathbb F}_p$
. One obtains a presentation of
$\overline {U}_{n+1}$
with generating set
$\{\overline {e}_{ij}:1\leq i\lt j\leq n+1\}$
, modulo the relations induced by the above relations for the
$e_{ij}$
, together with the relation
$\overline {e}_{1,n+1}=1$
.
3. Massey products and Galois algebras
In this section, we let
$p$
be a prime number and we let
$F$
be a field. With the exception of Proposition 3.6, we assume that
$\operatorname {char}(F)\neq p$
and that
$F$
contains a primitive
$p$
th root of unity
$\zeta$
.
3.1 Galois
$U_3$
-algebras
Let
$a,b\in F^\times$
, and suppose that
$(a,b)=0$
in
$\operatorname {Br}(F)$
. By Lemma 2.2, we may fix
$\alpha \in F_a^\times$
and
$\beta \in F_b^\times$
such that
$N_a(\alpha )=b$
and
$N_b(\beta )=a$
.
We write
$(\mathbb Z/p\mathbb Z)^2=\langle {\sigma _a,\sigma _b}\rangle$
, and we view
$F_{a,b}$
as a Galois
$(\mathbb Z/p\mathbb Z)^2$
-algebra as in § 2.1. The projection
$U_3\to \overline {U}_3=(\mathbb Z/p\mathbb Z)^2$
sends
$e_{12}\mapsto \sigma _a$
and
$e_{23}\mapsto \sigma _b$
. We define the following elements of
$U_3$
:
\begin{equation*} \sigma _a:= e_{12},\quad \sigma _b:= e_{23},\quad \tau := e_{13}=[\sigma _a,\sigma _b]. \end{equation*}
Suppose we are given
$x\in F_a^\times$
such that
\begin{align} (\sigma _a-1)x=\frac {b}{\alpha ^p}. \end{align}
The étale
$F$
-algebra
$K:= (F_{a,b})_x$
has the structure of a Galois
$U_3$
-algebra, such that the Galois
$(\mathbb Z/p\mathbb Z)^2$
-algebra
$K^{Q_3}$
is equal to
$F_{a,b}$
and
\begin{align} (\sigma _a-1)x^{1/p}=\frac {b^{1/p}}{\alpha },\quad (\sigma _b-1)x^{1/p}=1,\quad (\tau -1)x^{1/p}=\zeta ^{-1}. \end{align}
Similarly, suppose we are given
$y\in F_b^\times$
such that
\begin{align} (\sigma _b-1)y=\frac {a}{\beta ^p}. \end{align}
The étale
$F$
-algebra
$K:= (F_{a,b})_y$
has the structure of a Galois
$U_3$
-algebra, such that the Galois
$(\mathbb Z/p\mathbb Z)^2$
-algebra
$K^{Q_3}$
is equal to
$F_{a,b}$
and
\begin{align} (\sigma _a-1)y^{1/p}=1,\quad (\sigma _b-1)y^{1/p}=\frac {a^{1/p}}{\beta },\quad (\tau -1)y^{1/p}=\zeta . \end{align}
In (3.2) and (3.4), the relations involving
$\tau$
follows from the first two.
If
$x\in F_a^\times$
satisfies (3.1), then so does
$ax$
. We may thus apply (3.2) to
$(F_{a,b})_{ax}$
. Therefore,
$(F_{a,b})_{ax}$
has the structure of a Galois
$U_3$
-algebra, where
$U_3$
acts via
$\overline {U}_3=\operatorname {Gal}(F_{a,b}/F)$
on
$F_{a,b}$
and
\begin{equation*}(\sigma _a-1)(ax)^{1/p}=\frac {b^{1/p}}{\alpha },\quad (\sigma _b-1)(ax)^{1/p}=1,\quad (\tau -1)(ax)^{1/p}=\zeta ^{-1}.\end{equation*}
Similarly, if
$y\in F_b^\times$
satisfies (3.3), we may apply (3.4) to
$(F_{a,b})_{by}$
. Therefore,
$(F_{a,b})_{by}$
admits a Galois
$U_3$
-algebra structure, where
$U_3$
acts via
$\overline {U}_3=\operatorname {Gal}(F_{a,b}/F)$
on
$F_{a,b}$
and
\begin{equation}(\sigma _a-1)(by)^{1/p}=1,\quad (\sigma _b-1)(by)^{1/p}=\frac {a^{1/p}}{\beta },\quad (\tau -1)(by)^{1/p}=\zeta.\end{equation}
Lemma 3.1.
-
(1) Let
$x\in F_a^\times$
satisfy (
3.1
), and consider the Galois
$U_3$
-algebras
$(F_{a,b})_x$
and
$(F_{a,b})_{ax}$
as in (
3.2
). Then
$(F_{a,b})_x\simeq (F_{a,b})_{ax}$
as Galois
$U_3$
-algebras.
-
(2) Let
$y\in F_b^\times$
satisfy (
3.3
), and consider the Galois
$U_3$
-algebras
$(F_{a,b})_y$
and
$(F_{a,b})_{by}$
as in (
3.4
). Then
$(F_{a,b})_y\simeq (F_{a,b})_{by}$
as Galois
$U_3$
-algebras.
Proof.
(1) The automorphism
$\sigma _b\colon F_{a,b}\to F_{a,b}$
extends to an isomorphism of étale algebras
$f\colon (F_{a,b})_{ax}\to (F_{a,b})_x$
by sending
$(ax)^{1/p}$
to
$a^{1/p}x^{1/p}$
. The map
$f$
is well defined because
$f((ax)^{1/p})^p=(a^{1/p}x^{1/p})^p=ax$
. We now show that
$f$
is
$U_3$
-equivariant. The restriction of
$f$
to
$F_{a,b}$
is
$U_3$
-equivariant because
$\sigma _a\sigma _b=\sigma _b\sigma _a$
on
$F_{a,b}$
. We have
\begin{equation*} \sigma _a(f((ax)^{1/p}))=\sigma _a(a^{1/p})\cdot \sigma _a(x^{1/p})=\zeta \cdot a^{1/p}\cdot \frac {b^{1/p}}{\alpha }\cdot x^{1/p}=\frac {\zeta a^{1/p}b^{1/p}x^{1/p}}{\alpha } \end{equation*}
and
\begin{equation*}f(\sigma _a((ax)^{1/p}))=f((b^{1/p}/\alpha )\cdot (ax)^{1/p})=\zeta \cdot \frac {b^{1/p}}{\alpha }\cdot a^{1/p}\cdot x^{1/p}=\frac {\zeta a^{1/p}b^{1/p}x^{1/p}}{\alpha }.\end{equation*}
Thus,
$f$
is
$\langle {\sigma _a}\rangle$
-equivariant. We also have
\begin{equation*}\sigma _b(f((ax)^{1/p}))= \sigma _b(a^{1/p}) \cdot \sigma _b(x^{1/p}) = a^{1/p}\cdot x^{1/p} \end{equation*}
and
\begin{equation*}f(\sigma _b((ax)^{1/p}))=f((ax)^{1/p})=a^{1/p}\cdot x^{1/p}.\end{equation*}
Thus,
$f$
is
$\langle {\sigma _b}\rangle$
-equivariant. Since
$\sigma _a$
and
$\sigma _b$
generate
$U_3$
, we conclude that
$f$
is
$U_3$
-equivariant, as desired.
(2) The proof is similar to that of (1).
Proposition 3.2.
Let
$a,b\in F^\times$
be such that
$(a,b)=0$
in
$\operatorname {Br}(F)$
, and fix
$\alpha \in F_a^\times$
and
$\beta \in F_b^\times$
such that
$N_a(\alpha )=b$
and
$N_b(\beta )=a$
.
-
(1) Every Galois
$U_3$
-algebra
$K$
over
$F$
such that
$K^{Q_3}\simeq F_{a,b}$
as
$(\mathbb Z/p\mathbb Z)^2$
-algebras is of the form
$(F_{a,b})_x$
for some
$x\in F_a^\times$
as in (
3.1
), with
$U_3$
-action given by (
3.2
).
-
(2) Every Galois
$U_3$
-algebra
$K$
over
$F$
such that
$K^{Q_3}\simeq F_{a,b}$
as
$(\mathbb Z/p\mathbb Z)^2$
-algebras is of the form
$(F_{a,b})_y$
for some
$y\in F_b^\times$
as in (
3.3
), with
$U_3$
-action given by (
3.4
).
-
(3) Let
$(F_{a,b})_x$
and
$(F_{a,b})_y$
be Galois
$U_3$
-algebras as in (
3.2
) and (
3.4
), respectively. The Galois
$U_3$
-algebras
$(F_{a,b})_x$
and
$(F_{a,b})_y$
are isomorphic if and only if there exists
$w\in F_{a,b}^\times$
such that
\begin{align*}w^p=xy,\quad (\sigma _a-1)(\sigma _b-1)w=\zeta . \\[-24pt] \end{align*}
Proof.
(1) Since
$Q_3=\langle {\tau }\rangle \simeq \mathbb Z/p\mathbb Z$
and
$K^{Q_3}\simeq F_{a,b}$
as
$(\mathbb Z/p\mathbb Z)^2$
-algebras, we have an isomorphism of étale
$F_{a,b}$
-algebras
$K\simeq (F_{a,b})_z$
for some
$z\in F_{a,b}^\times$
such that
$(\tau -1)z^{1/p}=\zeta ^{-1}$
. We may suppose that
$K=(F_{a,b})_z$
. As
$\tau$
commutes with
$\sigma _b$
,
\begin{equation*} (\tau -1)(\sigma _b-1)z^{1/p}=(\sigma _b-1)(\tau -1)z^{1/p}=(\sigma _b-1)\zeta ^{-1}=1, \end{equation*}
and hence
$(\sigma _b-1)z^{1/p}\in F_{a,b}^\times$
. By Hilbert’s Theorem 90 for the extension
$F_{a,b}/F_a$
, there is
$t\in F_{a,b}^\times$
such that
$(\sigma _b-1)z^{1/p}=(\sigma _b-1)t$
. Replacing
$z$
by
$zt^{-p}$
, we may thus assume that
$(\sigma _b-1)z^{1/p}=1$
. In particular,
$z\in F_a^\times$
. Since
$(\tau -1)z^{1/p}=\zeta ^{-1}$
, we have
$\sigma _b\sigma _a(z^{1/p})=\zeta \sigma _a\sigma _b(z^{1/p})$
. Thus,
\begin{equation*}(\sigma _b-1) (\sigma _a-1)z^{1/p} =(\sigma _b\sigma _a-\sigma _a\sigma _b+ (\sigma _a-1)(\sigma _b-1))z^{1/p}=\zeta (\sigma _a-1) (\sigma _b-1)z^{1/p} = \zeta ,\end{equation*}
and hence
$(\sigma _a-1)z^{1/p} = b^{1/p}/\alpha '$
for some
$\alpha '\in F_a^\times$
. Moreover,
$N_a(\alpha '/\alpha )=b/b=1$
, and so by Hilbert’s Theorem 90 there exists
$\theta \in F_a^{\times }$
such that
$\alpha '/\alpha =(\sigma _a-1)\theta$
. We define
$x:= z\theta ^p\in F_a^\times$
, and we set
$x^{1/p}:= z^{1/p}\theta \in (F_{a,b})_z^\times$
. Then
$K=(F_{a,b})_x$
, where
\begin{equation*}(\sigma _a-1)x^{1/p}=(\sigma _a-1)z^{1/p}\cdot (\sigma _a-1)\theta =\frac {b^{1/p}}{\alpha '}\cdot \frac {\alpha '}{\alpha }=\frac {b^{1/p}}{\alpha },\end{equation*}
and
$(\sigma _b-1)x^{1/p}=1$
, as desired.
(2) The proof is analogous to that of (1).
(3) Suppose we are given an isomorphism of Galois
$U_3$
-algebras between
$(F_{a,b})_x$
and
$(F_{a,b})_y$
. Let
$t\in (F_{a,b})_x$
be the image of
$y^{1/p}$
under the isomorphism and set
\begin{equation*}w':= x^{1/p} t \in (F_{a,b})_x.\end{equation*}
Set
$y':= t^p$
. We have
$(\tau -1)w'=\zeta ^{-1}\cdot \zeta =1$
, and hence
$w'\in F_{a,b}^\times$
. We have
$(w')^p=xy'$
. Since
$F_b$
coincides with the
$\langle {\sigma _a,\tau }\rangle$
-invariant subalgebra of
$(F_{a,b})_x$
and
$(F_{a,b})_y$
, the isomorphism
$(F_{a,b})_y\to (F_{a,b})_x$
restricts to an isomorphism of Galois
$\mathbb Z/p\mathbb Z$
-algebras
$F_b \to F_b$
. Since the automorphism group of
$F_b$
as a Galois
$(\mathbb Z/p\mathbb Z)$
-algebra is
$\mathbb Z/p\mathbb Z$
, generated by
$\sigma _b$
, this isomorphism
$F_b \to F_b$
is equal to
$\sigma _b^i$
for some integer
$i\geq 0$
. Thus,
$y'=\sigma _b^i(y)$
. Define
\begin{equation*}w:= w' a^{-i/p}\mathop {{\prod }}\limits _{j=0}^i\sigma _b^{{\kern1.1pt}j}(\beta )\in F_{a,b}^\times .\end{equation*}
We have
$(1-\sigma _b)y=\beta ^p/a$
, and hence
\begin{align*}(1-\sigma _b^i)y= \biggl(\mathop {{\sum }}\limits _{j=0}^{i-1}\sigma _b^{{\kern1.1pt}j}(1-\sigma _b) \biggr)y= \biggl(\mathop {{\prod }}\limits _{j=0}^i\sigma _b^{{\kern1.1pt}j}(\beta ^p) \biggr)/a^i=w^p/(w')^p.\end{align*}
Therefore,
\begin{align} w^p=(w')^p(1-\sigma _b^i)y=x\sigma _b^i(y)(1-\sigma _b^i)y=xy. \end{align}
We have
$(\sigma _b-1)x^{1/p}=1$
and
\begin{equation*}(\sigma _a-1)(\sigma _b-1)t=(\sigma _a-1)(\sigma _b-1)y^{1/p}=(\sigma _a-1)(a^{1/p}/\beta )=\zeta .\end{equation*}
Therefore,
\begin{equation*}(\sigma _a-1)(\sigma _b-1)w'=(\sigma _a-1)(\sigma _b-1)t=\zeta .\end{equation*}
Since
$(\sigma _a-1)(\sigma _b-1)a^{1/p}=1$
and
$(\sigma _a-1)(\sigma _b-1)\beta =1$
, we conclude that
\begin{align} (\sigma _a-1)(\sigma _b-1)w=(\sigma _a-1)(\sigma _b-1)w'=\zeta . \end{align}
Putting (3.5) and (3.6) together, we see that
$w$
satisfies the conditions of (3). Conversely, suppose we are given
$w'\in F_{a,b}^\times$
such that
\begin{equation*}xy=(w')^p,\quad (\sigma _a-1)(\sigma _b-1)w'=\zeta .\end{equation*}
Claim 3.3.
There exists
$w\in F_{a,b}^\times$
such that
\begin{equation*}xy=w^p,\quad (\sigma _a-1)w=\zeta ^{-i}\frac {b^{1/p}}{\alpha },\quad (\sigma _b-1)w=\zeta ^{-j}\frac {a^{1/p}}{\beta }, \end{equation*}
for some integers
$i$
and
$j$
.
Proof of Claim 3.3
. First, we find
$\eta _a\in F_a^\times$
such that
\begin{align} \eta _a^p=1, \quad (\sigma _a-1)(w'/\eta _a)=\zeta ^{-i}\frac {b^{1/p}}{\alpha }. \end{align}
We have
\begin{equation*} (\sigma _a - 1) (w')^p=(\sigma _a - 1) x=\frac {b}{\alpha ^p}. \end{equation*}
Let
\begin{equation*}\zeta _a:= (\sigma _a-1)w'\cdot \alpha \cdot b^{-1/p}\in F_{a,b}^\times .\end{equation*}
We have
$\zeta _a^p=1$
. Moreover,
$(\sigma _b-1)\zeta _a=\zeta \cdot 1\cdot \zeta ^{-1}=1$
, that is,
$\zeta _a$
belongs to
$F_a^\times$
. If
$F_a$
is a field, this implies that
$\zeta _a=\zeta ^{-i}$
for some integer
$i$
, and (3.7) holds for
$\eta _a=1$
.
Suppose that
$F_a$
is not a field. Then
$F_a\simeq F^p$
, where
$\sigma _a$
acts on Fp
by cyclically permuting the coordinates, that is,
\begin{equation*}\sigma _a(x_1,x_2,\ldots ,x_p)=(x_2,\ldots ,x_p, x_1).\end{equation*}
We have
$\zeta _a=(\zeta _1,\ldots ,\zeta _p)$
in
$F_a=F^p$
, where
$\zeta _i\in F^\times$
is a
$p$
th root of unity for all
$i$
. We have
$N_a(\zeta _a)=N_a(\alpha )/b=1$
, and so
$\zeta _1\cdots \zeta _p=1$
. Inductively, define
$\eta _1:= 1$
and
$\eta _{i+1}:= \zeta _i\eta _i$
for all
$i=1,\ldots ,p-1$
. Then
\begin{equation*}\eta _1/\eta _p=(\eta _1/\eta _2)\cdot (\eta _2/\eta _3)\cdots (\eta _{p-1}/\eta _p)=\zeta _1^{-1}\zeta _2^{-1}\cdots \zeta _{p-1}^{-1}=\zeta _p.\end{equation*}
Therefore, the element
$\eta _a:= (\eta _1,\ldots ,\eta _p)\in F^p=F_a$
satisfies
$\eta _a^p=1$
and
\begin{equation*}(\sigma _a-1)\eta _a=(\eta _2/\eta _1,\ldots ,\eta _p/\eta _{p-1},\eta _1/\eta _p)=(\zeta _1,\ldots ,\zeta _{p-1},\zeta _p)=\zeta _a.\end{equation*}
Thus,
\begin{equation*}\eta _a^p=1,\quad (\sigma _a-1)(w'/\eta _a)=(\sigma _a-1)w'\cdot \zeta _a^{-1}=\frac {b^{1/p}}{\alpha },\end{equation*}
All in all, independent of whether
$F_a$
is a field or not, we have found
$\eta _a$
satisfying (3.7).
Similarly, we construct
$\eta _b\in F_b^\times$
such that
\begin{align} \eta _b^p=1,\quad (\sigma _b-1)(w'/\eta _b)=\zeta ^{-j}\frac {a^{1/p}}{\beta }, \end{align}
for some integer
$j$
. Set
$w:= w'/(\eta _a\eta _b)\in F_{a,b}^\times$
. Putting together (3.7) and (3.8), we deduce that
$w$
satisfies the conclusion of Claim 3.3.
Let
$w\in F_{a,b}^\times$
be as in Claim 3.3. By Lemma 3.1(1), applied
$i$
times, the Galois
$U_3$
-algebra
$(F_{a,b})_x$
is isomorphic to
$(F_{a,b})_{a^ix}$
, where
\begin{equation*}(\sigma _a-1)(a^ix)^{1/p}=\frac {b^{1/p}}{\alpha },\quad (\sigma _b-1)(a^ix)^{1/p}=1.\end{equation*}
By Lemma 3.1(2), applied
$j$
times, the Galois
$U_3$
-algebra
$(F_{a,b})_y$
is isomorphic to
$(F_{a,b})_{b^{{\kern1.1pt}j}y}$
, where
\begin{equation*}(\sigma _a-1)(b^{{\kern1.1pt}j}y)^{1/p}=1,\quad (\sigma _b-1)(b^{{\kern1.1pt}j}y)^{1/p}=\frac {a^{1/p}}{\beta }.\end{equation*}
Thus, it suffices to construct an isomorphism of
$U_3$
-algebras
$(F_{a,b})_{a^ix}\simeq (F_{a,b})_{b^{{\kern1.1pt}j}y}$
. Let
\begin{equation*}\tilde {w}:= wa^{i/p}b^{{\kern1.1pt}j/p}\in F_{a,b}^\times ,\end{equation*}
so that
\begin{equation*}(\sigma _a-1)\tilde {w}=\frac {b^{1/p}}{\alpha },\quad (\sigma _b-1)\tilde {w}=\frac {a^{1/p}}{\beta }.\end{equation*}
Let
$f\colon (F_{a,b})_{a^ix}\to (F_{a,b})_{b^{{\kern1.1pt}j}y}$
be the isomorphism of étale algebras which is the identity on
$F_{a,b}$
and sends
$(a^ix)^{1/p}$
to
$\tilde {w}/(b^{{\kern1.1pt}j}y)^{1/p}$
. Note that
$f$
is well defined because
\begin{equation*}(\tilde {w})^p=wa^ib^{{\kern1.1pt}j}=(a^ix)(b^{{\kern1.1pt}j}y).\end{equation*}
Moreover,
\begin{align*}(\sigma _a-1) (\tilde {w}/(b^{{\kern1.1pt}j}y)^{1/p})=\frac {b^{1/p}}{\alpha }=(\sigma _a-1)(a^ix)^{1/p}, \\[-24pt] \end{align*}
\begin{equation*}(\sigma _b-1) (\tilde {w}/(b^{{\kern1.1pt}j}y)^{1/p})=\frac {a^{1/p}}{\beta }\cdot \frac {\beta }{a^{1/p}}=1=(\sigma _b-1)(a^ix)^{1/p},\end{equation*}
and hence
$f$
is
$U_3$
-equivariant.
3.2 Galois
$\overline {U}_4$
-algebras
Let
$a,b,c\in F^\times$
be such that
$(a,b)=(b,c)=0$
in
$\operatorname {Br}(F)$
. By Lemma 2.2, we may fix
$\alpha \in F_a^\times$
and
$\gamma \in F_c^\times$
such that
$N_a(\alpha )=N_c(\gamma )=b$
. We have
$\operatorname {Gal}(F_{a,b,c}/F)=(\mathbb Z/p\mathbb Z)^3=\langle {\sigma _a,\sigma _b,\sigma _c}\rangle$
. The projection map
$\overline {U}_4\to (\mathbb Z/p\mathbb Z)^3$
is given by
$\overline {e}_{12}\mapsto \sigma _a$
,
$\overline {e}_{23}\mapsto \sigma _b$
,
$\overline {e}_{34}\mapsto \sigma _c$
. Its kernel
$\overline {Q}_4\subset \overline {U}_4$
is isomorphic to
$(\mathbb Z/p\mathbb Z)^2$
, generated by
$\overline {e}_{13}$
and
$\overline {e}_{24}$
. We define the following elements of
$\overline {U}_4$
:
\begin{equation*}\sigma _a:= \overline {e}_{12},\quad \sigma _b:= \overline {e}_{23},\quad \sigma _c:= \overline {e}_{34},\quad \tau _{ab}:= \overline {e}_{13},\quad \tau _{bc}:= \overline {e}_{24}.\end{equation*}
Let
$x\in F_a^\times$
and
$x'\in F_c^\times$
be such that
\begin{align} (\sigma _a-1)x=\frac {b}{\alpha ^p},\quad (\sigma _c-1)x'=\frac {b}{\gamma ^p}, \end{align}
and consider the Galois
$\overline {U}_4$
-algebra
$K:= (F_{a,b,c})_{x,x'}$
, where
$\overline {U}_4$
acts on
$F_{a,b,c}$
via the surjection onto
$\operatorname {Gal}(F_{a,b,c}/F)$
, and
\begin{align} (\sigma _a-1)x^{1/p}=\frac {b^{1/p}}{\alpha },\quad (\sigma _b-1)x^{1/p}=1,\quad (\sigma _c-1)x^{1/p}=1, \\[-24pt] \nonumber \end{align}
\begin{align} (\tau _{ab}-1)x^{1/p}=\zeta ^{-1},\quad (\tau _{bc}-1)x^{1/p}=1, \\[-24pt] \nonumber \end{align}
\begin{align} (\sigma _a-1)(x')^{1/p}=1,\quad (\sigma _b-1)(x')^{1/p}=1,\quad (\sigma _c-1)(x')^{1/p}=\frac {b^{1/p}}{\gamma }, \end{align}
\begin{align} (\tau _{ab}-1)(x')^{1/p}=1,\quad (\tau _{bc}-1)(x')^{1/p}=\zeta . \\[6pt] \nonumber \end{align}
Note that (3.11) follows from (3.10) and (3.13) follows from (3.12). We leave to the reader to check that the relations (2.8)–(2.12) are satisfied.
Proposition 3.4.
Let
$a,b,c\in F^\times$
be such that
$(a,b)=(b,c)=0$
in
$\operatorname {Br}(F)$
. Fix
$\alpha \in F_a^\times$
and
$\gamma \in F_c^\times$
such that
$N_a(\alpha )=N_c(\gamma )=b$
. Let
$K$
be a Galois
$\overline {U}_4$
-algebra such that
$K^{\overline {Q}_4}\simeq F_{a,b,c}$
as
$(\mathbb Z/p\mathbb Z)^3$
-algebras. Then there exist
$x\in F_a^\times$
and
$x'\in F_c^\times$
such that
$K\simeq (F_{a,b,c})_{x,x'}$
as Galois
$\overline {U}_4$
-algebras, where
$\overline {U}_4$
acts on
$(F_{a,b,c})_{x,x'}$
by (
3.10
)–(
3.13
).
Proof.
Let
$H$
(respectively,
$H'$
) be the subgroup of
$\overline {U}_4$
generated by
$\sigma _c$
and
$\tau _{bc}$
(respectively,
$\sigma _a$
and
$\tau _{ab}$
), and let
$S$
be the subgroup of
$\overline {U}_4$
generated by
$H$
and
$H'$
. Note that
$K^H$
is a Galois
$U_3$
-algebra over
$F$
such that
$(K^H)^{Q_3}\simeq F_{a,b}$
as
$(\mathbb Z/p\mathbb Z)^2$
-algebras and
$K^S\simeq F_b$
as
$(\mathbb Z/p\mathbb Z)$
-algebras. Thus, by Proposition 3.2(1), there exists
$x\in F_a^\times$
such that
$K^H\simeq (F_{a,b})_x$
as Galois
$U_3$
-algebras. Similarly, by Proposition 3.2(2), there exists
$x'\in F_c^\times$
such that
$K^{H'}\simeq (F_{b,c})_{x'}$
as Galois
$U_3$
-algebras. Therefore,
$x$
satisfies (3.10) and
$x'$
satisfies (3.12). We apply Lemma 2.1(2) to (2.14). We obtain the isomorphisms of
$\overline {U}_4$
-algebras
\begin{equation*}K\simeq K^H\otimes _{K^S}K^{H'}\simeq (F_{a,b,c})_{x,x'},\end{equation*}
where
$(F_{a,b,c})_{x,x'}$
is the
$\overline {U}_4$
-algebra determined by (3.10) and (3.12).
3.3 Galois
$U_4$
-algebras
Let
$a,b,c\in F^\times$
, and suppose that
$(a,b)=(b,c)=0$
in
$\operatorname {Br}(F)$
. We write
$(\mathbb Z/p\mathbb Z)^3=\langle {\sigma _a,\sigma _b,\sigma _c}\rangle$
and view
$F_{a,b,c}$
as a Galois
$(\mathbb Z/p\mathbb Z)^3$
-algebra over
$F$
, as in § 2.1. The quotient map
$U_4\to (\mathbb Z/p\mathbb Z)^3$
is given by
$e_{12}\mapsto \sigma _a$
,
$e_{23}\mapsto \sigma _b$
and
$e_{34}\mapsto \sigma _c$
. The kernel
$Q_4$
of this homomorphism is generated by
$e_{13}$
,
$e_{24}$
and
$e_{14}$
and is isomorphic to
$(\mathbb Z/p\mathbb Z)^3$
. We define the following elements of
$U_4$
:
\begin{align*} \sigma _a:= e_{12},\quad \sigma _b:= e_{23},\quad \sigma _c:= e_{34}, \\[-24pt] \end{align*}
\begin{equation*} \tau _{ab}:= e_{13}=[\sigma _a,\sigma _b],\quad \tau _{bc}:= e_{24}=[\sigma _b,\sigma _c],\quad \rho := e_{14}=[\sigma _a,\tau _{bc}]=[\tau _{ab},\sigma _c]. \end{equation*}
Proposition 3.5.
Let
$a,b,c\in F^\times$
be such that
$(a,b)=(b,c)=0$
in
$\operatorname {Br}(F)$
. Let
$\alpha \in F_a^\times$
and
$\gamma \in F_c^\times$
be such that
$N_a(\alpha )=b$
and
$N_c(\gamma )=b$
. Let
$K$
be a Galois
$\overline {U}_4$
-algebra such that
$K^{\overline {Q}_4}\simeq F_{a,b,c}$
as
$(\mathbb Z/p\mathbb Z)^3$
-algebras.
There exists a Galois
$U_4$
-algebra
$L$
over
$F$
such that
$L^{Z_4}\simeq K$
as
$\overline {U}_4$
-algebras if and only if there exist
$u,u'\in F_{a,c}^\times$
such that
\begin{equation*}\alpha \cdot (\sigma _a-1)u=\gamma \cdot (\sigma _c-1)u'\end{equation*}
and such that
$K$
is isomorphic to the Galois
$\overline {U}_4$
-algebra
$(F_{a,b,c})_{x,x'}$
determined by (
3.10
)–(
3.13
), where
$x=N_c(u)\in F_a^\times$
and
$x'=N_a(u')\in F_c^\times$
.
Proof.
Suppose that
$K=(F_{a,b,c})_{x,x'}$
, with
$\overline {U}_4$
-action determined by (3.10)–(3.13). Let
$L$
be a Galois
$U_4$
-algebra over
$F$
such that
$L^{Z_4}=K$
, and let
$y\in K^\times$
be such that
$L=K_y$
.
We have
$\operatorname {Gal}(L/F_{a,b,c})=Q_4=\langle {\tau _{ab}, \tau _{bc},\rho }\rangle \simeq (\mathbb Z/p\mathbb Z)^3$
, and hence one may choose
$y$
in
$F_{a,b,c}^\times$
and such that
\begin{equation*} (\tau _{ab}-1)y^{1/p}=1,\quad (\tau _{bc}-1)y^{1/p}=1,\quad (\rho -1)y^{1/p}=\zeta ^{-1}. \end{equation*}
The element
$\sigma _b$
commutes with
$\tau _{ab}, \tau _{bc}$
and
$\rho$
. Hence,
\begin{equation*} \tau _{ab}(\sigma _b-1)(y^{1/p})=(\sigma _b-1)\tau _{ab}(y^{1/p})=(\sigma _b-1)(y^{1/p}). \end{equation*}
Similarly,
\begin{equation*} \tau _{bc}(\sigma _b-1)(y^{1/p})=(\sigma _b-1)(y^{1/p}) \end{equation*}
and
\begin{equation*}\rho (\sigma _b-1)(y^{1/p})=(\sigma _b-1)(\zeta \cdot y^{1/p})=(\sigma _b-1)(y^{1/p}).\end{equation*}
It follows that
$(\sigma _b-1)(y^{1/p})\in F_{a,b,c}^\times$
. By Hilbert’s Theorem 90, applied to
$F_{a,b,c}/F_{a,c}$
, there is
$q\in F_{a,b,c}^\times$
such that
$(\sigma _b-1)(y^{1/p})=(\sigma _b-1)q$
. Replacing
$y$
by
$y/ q^p$
, we may assume that
$\sigma _b(y^{1/p})=y^{1/p}$
. In particular,
$y\in F_{a,c}^\times$
. We have
\begin{align*} \rho (\sigma _a-1) (y^{1/p})= &\ (\sigma _a -1)\rho (y^{1/p})=(\sigma _a -1)(\zeta ^{-1}\cdot y^{1/p})=(\sigma _a -1)(y^{1/p}), \\ \sigma _b(\sigma _a-1) (y^{1/p})= &\ (\sigma _a\sigma _b{\tau _{ab}}^{-1} -\sigma _b)(y^{1/p})=(\sigma _a-1) (y^{1/p}),\\ \tau _{ab}(\sigma _a-1) (y^{1/p})= &\ (\sigma _a -1)\tau _{ab}(y^{1/p})=(\sigma _a -1)(y^{1/p}),\\ \tau _{bc}(\sigma _a-1) (y^{1/p})= &\ (\rho ^{-1} \sigma _a -1)\tau _{bc}(y^{1/p})=( \sigma _a \rho ^{-1} -1)(y^{1/p})=\zeta \cdot (\sigma _a-1) (y^{1/p}). \end{align*}
By (3.12)–(3.13), analogous identities are satisfied by
$(x')^{1/p}$
, that is,
\begin{equation*}(\rho -1)(x')^{1/p}=(\sigma _b-1)(x')^{1/p}=(\tau _{ab}-1)(x')^{1/p}=1,\quad (\tau _{bc}-1)(x')^{1/p}=\zeta .\end{equation*}
Therefore,
\begin{equation*} (\sigma _a-1) (y^{1/p})=\frac {(x')^{1/p}}{u'}, \end{equation*}
for some
$u'\in F_{a,c}^\times$
. In particular,
$x'= N_a(u')$
. A similar computation shows that
\begin{equation*} (\sigma _c-1) (y^{1/p})=\frac {x^{1/p}}{u}, \end{equation*}
for some
$u\in F_{a,c}^\times$
. In particular,
$x= N_c(u)$
. In addition,
\begin{equation*} \frac {b^{1/p}}{\alpha }=(\sigma _a-1) (x^{1/p})=(\sigma _a-1) [u\cdot (\sigma _c-1)(y^{1/p})], \end{equation*}
\begin{equation*} \frac {b^{1/p}}{\gamma }=(\sigma _c-1) ((x')^{1/p})=(\sigma _c-1) [u'\cdot (\sigma _a-1)(y^{1/p})]. \end{equation*}
Therefore,
\begin{equation*}\alpha \cdot (\sigma _a-1)u=\gamma \cdot (\sigma _c-1)u'.\end{equation*}
Conversely, suppose we are given
$u,u'\in F_{a,c}^\times$
such that
\begin{equation*}\alpha \cdot (\sigma _a-1)u=\gamma \cdot (\sigma _c-1)u',\quad x=N_c(u),\quad x'=N_a(u').\end{equation*}
Then
\begin{equation*} (\sigma _a-1)x=(\sigma _a-1)N_c(u)=N_c(\sigma _a-1)u=N_c\Big(\frac {\gamma }{\alpha }\Big)=\frac {b}{\alpha ^p}, \end{equation*}
\begin{equation*} (\sigma _c-1)x'=(\sigma _c-1)N_a(u')=N_a(\sigma _c-1)u'=N_a\Big(\frac {\alpha }{\gamma }\Big)=\frac {b}{\gamma ^p}. \end{equation*}
We have
\begin{equation*} N_c \Big(\frac {x}{u^p}\Big)=\frac {N_c(x)}{N_c(u^p)}=\frac {x^p}{x^p}=1, \end{equation*}
\begin{equation*} N_a \Big(\frac {x'}{(u')^p}\Big)=\frac {N_a(x')}{N_a((u')^p)}=\frac {(x')^p}{(x')^p}=1, \end{equation*}
\begin{equation*} (\sigma _a-1)\Big(\frac {x}{u^p}\Big)=\frac {b}{\alpha ^p\cdot (\sigma _a-1)u^p}= \frac {b}{\gamma ^p\cdot (\sigma _c-1)(u')^p}=(\sigma _c-1)\Big(\frac {x'}{(u')^p}\Big). \end{equation*}
By Hilbert’s Theorem 90 applied to
$F_{a,c}/F$
, there is
$y\in F_{a,c}^\times$
such that
\begin{equation*} (\sigma _a-1)y=\frac {x'}{(u')^p} \quad \text {and}\quad (\sigma _c-1)y=\frac {x}{u^p}. \end{equation*}
We consider the étale
$F$
-algebra
$L:= K_y$
and make it into a Galois
$U_4$
-algebra such that
$L^{Z_4}=K$
. It suffices to describe the
$U_4$
-action on
$y^{1/p}$
. We set
\begin{equation*} (\sigma _a-1)(y^{1/p})=\frac {(x')^{1/p}}{u'},\quad (\sigma _b-1)(y^{1/p})=1,\quad (\sigma _c-1)(y^{1/p})=\frac {x^{1/p}}{u}. \end{equation*}
One can check that this definition is compatible with relations (2.4)–(2.7), and hence that it makes
$L$
into a Galois
$U_4$
-algebra such that
$L^{Z_4}=K$
.
We use Proposition 3.5 to give an alternative proof for the Massey vanishing conjecture for
$n=3$
and arbitrary
$p$
.
Proposition 3.6.
Let
$p$
be a prime, let
$F$
be a field and let
$\chi _1,\chi _2,\chi _3\in H^1(F,\mathbb Z/p\mathbb Z)$
. The following are equivalent.
-
(1) We have
$\chi _1\cup \chi _2=\chi _2 \cup \chi _3=0$
in
$H^2(F,\mathbb Z/p\mathbb Z)$
. -
(2) The Massey product
$\langle {\chi _1,\chi _2,\chi _3}\rangle \subset H^2(F,\mathbb Z/p\mathbb Z)$
is defined.
-
(3) The Massey product
$\langle {\chi _1,\chi _2,\chi _3}\rangle \subset H^2(F,\mathbb Z/p\mathbb Z)$
vanishes.
Proof.
It is clear that (3) implies (2) and that (2) implies (1). We now prove that (1) implies (3). The first part of the proof is a reduction to the case when
$\operatorname {char}(F)\neq p$
and
$F$
contains a primitive
$p$
th root of unity, and it follows [Reference Mináč and TânMT16, Proposition 4.14].
Consider the short exact sequence
\begin{align} 1\to Q_4\to U_4\to (\mathbb Z/p\mathbb Z)^3\to 1, \end{align}
where the map
$U_4\to (\mathbb Z/p\mathbb Z)^3$
comes from (2.13). Recall from the paragraph preceding Proposition 3.5 that the group
$Q_4$
is abelian. Therefore, the group homomorphism
$\chi :=(\chi _1,\chi _2,\chi _3)\colon \Gamma _F \to (\mathbb Z/p\mathbb Z)^3$
induces a pullback map
\begin{equation*}H^2((\mathbb Z/p\mathbb Z)^3, Q_4)\to H^2(F, Q_4).\end{equation*}
We let
$A\in H^2(F, Q_4)$
be the image of the class of (3.14) under this map. By Theorem 2.4, for every finite extension
$F'/F$
the Massey product
$\langle {\chi _1,\chi _2,\chi _3}\rangle$
vanishes over
$F'$
if and only if the restriction of
$\chi$
to
$\Gamma _{F'}$
lifts to
$U_4$
, and this happens if and only if
$A$
restricts to zero in
$H^2(F', Q_4)$
.
When
$\operatorname {char}(F)=p$
, we have
$\operatorname {cd}_p(F)\leq 1$
by [Reference Serre and IonSer97, § 2.2, Proposition 3]. Therefore,
$H^2(F,Q_4)=0$
and hence
$A=0$
. Thus, (1) implies (3) when
$\operatorname {char}(F)=p$
.
Suppose that
$\operatorname {char}(F)\neq p$
. There exists an extension
$F'/F$
of prime-to-
$p$
degree such that
$F'$
contains a primitive
$p$
th root of
$1$
. If (1) implies (3) for
$F'$
, then
$A$
restricts to zero in
$H^2(F', Q_4)$
. By a restriction-corestriction argument, we deduce that
$A$
vanishes, that is, (1) implies (3) for
$F$
. Thus, we may assume that
$F$
contains a primitive
$p$
th root of unity
$\zeta$
.
Let
$a,b,c\in F^\times$
be such that
$\chi _a=\chi _1$
,
$\chi _b=\chi _2$
and
$\chi _c=\chi _3$
in
$H^1(F,\mathbb Z/p\mathbb Z)$
. Since
$(a,b)=(b,c)=0$
in
$\operatorname {Br}(F)$
, there exists
$\alpha \in F_a^\times$
and
$\gamma \in F_c^\times$
such that
$N_a(\alpha )=N_c(\gamma )=b$
. Since
$N_{ac}(\gamma /\alpha )=N_c(\gamma )/N_a(\alpha )=1$
in
$F_{ac}^\times$
, by Hilbert’s Theorem 90 there exists
$t\in F_{a,c}^\times$
such that
$\gamma /\alpha = (\sigma _a\sigma _c - 1)t$
. Define
$u,u'\in F_{a,c}^\times$
by
$u:= \sigma _c(t)$
and
$u':= t^{-1}$
. Then
\begin{equation*}\alpha \cdot (\sigma _a-1)u=\alpha \cdot (\sigma _a\sigma _c-\sigma _c)t= \alpha \cdot (\sigma _a\sigma _c-1)t\cdot (\sigma _c-1)t^{-1}=\gamma \cdot (\sigma _c-1)u'.\end{equation*}
Let
$x:= N_c(u)\in F_a^\times$
and
$x':= N_a(u')\in F_c^\times$
. Since
$\sigma _a\sigma _c=\sigma _c\sigma _a$
on
$F_{a,c}^\times$
,
\begin{equation*}(\sigma _a-1)x=N_c((\sigma _a-1)u)=N_c((\sigma _c-1)u'\cdot (\gamma /\alpha ))=N_c(\gamma )/N_c(\alpha )=b/\alpha ^p.\end{equation*}
Similarly,
$(\sigma _c-1)x'=b/\gamma ^p$
. Therefore,
$x,x'$
satisfy (3.9). Let
$K:= (F_{a,b,c})_{x,x'}$
be the Galois
$\overline {U}_4$
-algebra over
$F$
, with the
$\overline {U}_4$
-action given by (3.10)–(3.13). By Proposition 3.5, there exists a Galois
$U_4$
-algebra
$L$
over
$F$
such that
$L^{Z_4}\simeq (F_{a,b,c})_{x,x'}$
as
$\overline {U}_4$
-algebras. In particular,
$L^{Q_4}\simeq F_{a,b,c}$
as
$(\mathbb Z/p\mathbb Z)^3$
-algebras. By Corollary 2.5, we conclude that
$\langle {a,b,c}\rangle$
vanishes.
3.4 Galois
$\overline {U}_5$
-algebras
Let
$a,b,c,d\in F^\times$
. We write
$(\mathbb Z/p\mathbb Z)^4=\langle {\sigma _a,\sigma _b,\sigma _c,\sigma _d}\rangle$
and regard
$F_{a,b,c,d}$
as a Galois
$(\mathbb Z/p\mathbb Z)^4$
-algebra over
$F$
as in § 2.1.
Proposition 3.7.
Let
$a,b,c,d \in F^\times$
be such that
$(a,b)=(b,c)=(c,d)=0$
in
$\operatorname {Br}(F)$
. The Massey product
$\langle {a,b,c,d}\rangle$
is defined if and only if there exist
$u\in F_{a,c}^\times$
,
$v\in F_{b,d}^\times$
and
$w\in F_{b,c}^\times$
such that
\begin{equation*}N_a(u)\cdot N_d(v) = w^p,\quad (\sigma _b - 1)(\sigma _c - 1)w = \zeta .\end{equation*}
Proof.
Denote by
$U_4^+$
and
$U_4^-$
the top-left and bottom-right
$4\times 4$
corners of
$U_5$
, respectively, and let
$S:= U_4^+\cap U_4^-$
be the middle subgroup
$U_3$
. Let
$Q_4^+$
and
$Q_4^-$
be the kernels of the maps
$U_4^+\to (\mathbb Z/p\mathbb Z)^3$
and
$U_4^-\to (\mathbb Z/p\mathbb Z)^3$
, respectively, and let
$P_4^+$
and
$P_4^-$
be the kernels of the maps
$U_4^+\to U_3$
and
$U_4^-\to U_3$
, respectively.
Suppose
$\langle a,b,c,d \rangle$
is defined. By Corollary 2.5, there exists a
$\overline {U}_5$
-algebra
$L$
such that
$L^{\overline {Q}_5}\simeq F_{a,b,c,d}$
as
$(\mathbb Z/p\mathbb Z)^4$
-algebras. Using Lemma 2.2, we fix
$\alpha \in F_a^\times$
and
$\gamma \in F_c^\times$
such that
$N_a(\alpha )=b$
and
$N_c(\gamma )=b$
. By Proposition 3.5, there exist
$u,u'\in F_{a,c}^\times$
such that, letting
$x':= N_c(u')$
and
$x:= N_a(u)$
, the
$\overline {U}_4^+$
-algebra
$K_1$
induced by
$L$
is isomorphic to the
$\overline {U}_4^+$
-algebra
$(F_{a,b,c})_{x',x}$
, where
$\overline {U}_4^+$
acts via (3.10)–(3.13), and where the roles of
$x$
and
$x'$
have been switched.
Similarly, there exist
$v,v'\in F_{b,d}^\times$
such that, letting
$z:= N_d(v)$
and
$z':= N_b(v')$
, the
$\overline {U}^-_4$
-algebra
$K_2$
induced by
$L$
is isomorphic to
$(F_{b,c,d})_{z,z'}$
. Since the
$U_3$
-algebras
$(K_1)^{P_4^+}$
and
$(K_2)^{P_4^-}$
are equal, by Proposition 3.2(3) there exists
$w\in F_{b,c}^\times$
such that
\begin{equation*} N_a(u)\cdot N_d(v) = xz = w^p,\quad (\sigma _b -1)(\sigma _c -1)w = \zeta . \end{equation*}
Conversely, let
$u\in F_{a,c}^\times$
,
$v\in F_{b,d}^\times$
, and
$w\in F_{b,c}^\times$
be such that
\begin{equation*} N_a(u)\cdot N_d(v) = w^p,\quad (\sigma _b -1)(\sigma _c -1)w = \zeta .\end{equation*}
By Lemma 2.2, there exist
$\alpha \in F_a^\times$
and
$\delta \in F_d^\times$
such that
$N_a(\alpha )=b$
and
$N_d(\delta )=c$
. We may write
\begin{equation*} (\sigma _b - 1)w = \frac {c^{1/p}}{\beta },\quad (\sigma _c - 1)w = \frac {b^{1/p}}{\gamma }, \end{equation*}
for some
$\beta \in F_b^\times$
and
$\gamma \in F_c^\times$
. We have
\begin{equation*} N_a((\sigma _c - 1)u\cdot (\gamma /\alpha )) = (\sigma _c - 1)N_a(u)\cdot N_a(\gamma /\alpha )= (\sigma _c - 1)w^p \cdot (\gamma ^p/b) = 1. \end{equation*}
By Hilbert’s Theorem 90, there is
$u'\in F_{a,c}^\times$
such that
\begin{equation*} \alpha \cdot (\sigma _a - 1)u' = \gamma \cdot (\sigma _c - 1)u. \end{equation*}
By Proposition 3.5, we obtain a Galois
$U_4^+$
-algebra
$K_1$
over
$F$
with the property that
$(K_1)^{Q_4^+}\simeq F_{a,b,c}$
as
$(\mathbb Z/p\mathbb Z)^3$
-algebras. Similarly, we get a Galois
$U_4^-$
-algebra over
$F$
such that
$(K_2)^{Q_4^-}\simeq F_{b,c,d}$
as
$(\mathbb Z/p\mathbb Z)^3$
-algebras. Since
$N_a(u)\cdot N_d(v) = w^p$
and
$(\sigma_b-1)(\sigma_c-1)w=\zeta$
, by Proposition 3.2(3) the
$U_3$
-algebras
$(K_1)^{P_4^+}$
and
$(K_2)^{P_4^-}$
are isomorphic. Now Lemma 2.1 applied to the cartesian square (2.14) for
$n=4$
yields a
$\overline {U}_5$
-Galois algebra
$L$
such that
$L^{Q_5}\simeq F_{a,b,c,d}$
as
$(\mathbb Z/p\mathbb Z)^4$
-algebras. By Corollary 2.5, this implies that
$\langle {a,b,c,d}\rangle$
is defined.
Lemma 3.8.
Let
$b,c\in F^\times$
and
$w\in F_{b,c}^{\times }$
. We have
$(\sigma _b-1)(\sigma _c-1)w=1$
if and only if there exist
$w_b\in F_b^\times$
and
$w_c\in F_c^\times$
such that
$w=w_bw_c$
in
$F_{b,c}^\times$
.
Proof.
We have
$(\sigma _b-1)(\sigma _c-1)(w_bw_c)=(\sigma _b-1)w_c=1$
for all
$w_b\in F_b^\times$
and
$w_c\in F_c^\times$
. Conversely, if
$w\in F_{b,c}^\times$
satisfies
$(\sigma _b-1)(\sigma _c-1)w=1$
, then
$(\sigma _c-1)w\in F_c^\times$
and
$N_c((\sigma _c-1)w)=1$
, and hence by Hilbert’s Theorem 90 there exists
$w_c\in F_c^\times$
such that
$(\sigma _c-1)w_c=(\sigma _c-1)w$
. Letting
$w_b:= w/w_c\in F_{b,c}^\times$
, we have
\begin{equation*}(\sigma _c-1)w_b=(\sigma _c-1)(w/w_c)=1,\end{equation*}
that is,
$w_b\in F_b^{\times }$
.
From Proposition 3.7, we derive the following necessary condition for a fourfold Massey product to be defined.
Proposition 3.9.
Let
$p$
be a prime, let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
, let
$a,b,c,d\in F^\times$
, and suppose that
$\langle {a,b,c,d}\rangle$
is defined over
$F$
. For every
$w\in F_{b,c}^\times$
such that
$(\sigma _b-1)(\sigma _c-1)w=\zeta$
, there exist
$u\in F_{a,c}^\times$
and
$v\in F_{b,d}^\times$
such that
$N_a(u)N_d(v)=w^p$
.
Proof.
By Proposition 3.7, there exist
$u_0\in F_{a,c}^\times$
,
$v_0\in F_{b,d}^\times$
and
$w_0\in F_{b,c}^\times$
such that
\begin{equation*}N_a(u_0) \cdot N_d(v_0) =w_0^p,\quad (\sigma _b-1)(\sigma _c-1)w_0=\zeta .\end{equation*}
We have
$(\sigma _b-1)(\sigma _c-1)(w_0/w)=1$
. By Lemma 3.8, this implies that
$w_0=w w_b w_c$
, where
$w_b\in F_b^\times$
and
$w_c\in F_c^\times$
. If we define
$u=u_0 w_c$
and
$v=v_0 w_b$
, then
\begin{equation}N_a(u)N_d(v)=N_a(u_0)N_a(w_c)N_d(v_0)N_d(w_b)=w_0^pw_c^pw_b^p=w^p.\end{equation}
4. A generic variety
In this section, we let
$p$
be a prime number, and we let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
.
Let
$b,c\in F^\times$
, and let
$X$
be the Severi–Brauer variety associated to
$(b,c)$
over
$F$
; see [Reference Gille and SzamuelyGS17, Chapter 5]. For every étale
$F$
-algebra
$K$
, we have
$(b,c)=0$
in
$\operatorname {Br}(K)$
if and only if
$X_K\simeq \mathbb P^{p-1}_K$
over
$K$
. In particular,
$X_b\simeq \mathbb{P}^{p-1}_b\ \text{over}\ {F_b}$
. (Recall that we write (
$\mathbb{P}^{p-1}_b\ \textrm{for}\ \mathbb{P}^{p-1}_{F_b}$
.) By [Reference Gille and SzamuelyGS17, Theorem 5.4.1], the central simple algebra
$(b,c)$
is split over
$F(X)$
.
We define the degree map
$\deg \colon \operatorname {Pic}(X)\to \mathbb Z$
as the composite of the pullback map
$\operatorname {Pic}(X)\to \operatorname {Pic}(X_b)\simeq \operatorname {Pic}(\mathbb P^{p-1}_b)$
and the degree isomorphism
$\operatorname {Pic}(\mathbb P^{p-1}_b)\to \mathbb Z$
. This does not depend on the choice of isomorphism
$X_b\simeq \mathbb P^{p-1}_b$
.
Lemma 4.1.
Let
$b,c\in F^\times$
, let
$G_b:= \operatorname {Gal}(F_b/F)$
and let
$X$
be the Severi–Brauer variety of
$(b,c)$
over
$F$
. Let
$s_1,\ldots ,s_p$
be homogeneous coordinates on
$\mathbb P^{p-1}_F$
.
-
(1) There exists a
$G_b$
-equivariant isomorphism
$X_b\xrightarrow {\sim } \mathbb P_b^{p-1}$
, where
$G_b$
acts on
$X_b$
via its action on
$F_b$
, and on
$\mathbb P^{p-1}_b$
by
\begin{equation*}\sigma _b^*(s_1)=cs_p,\quad \sigma _b^*(s_i)=s_{i-1}\quad (i=2,\ldots ,p).\end{equation*}
-
(2) If
$(b,c)\neq 0$
in
$\operatorname {Br}(F)$
, the image of
$\deg \colon \operatorname {Pic}(X)\to \mathbb Z$
is equal to
$p\mathbb Z$
. -
(3) There exists a rational function
$w\in F_{b,c}(X)^\times$
such that
and
\begin{equation*}(\sigma _b-1)(\sigma _c-1)w=\zeta \end{equation*}
where
\begin{equation*}\operatorname {div}(w)=x-y\quad \text {in $\operatorname {Div}(X_{b,c})$},\end{equation*}
$x,y\in (X_{b,c})^{(1)}$
satisfy
$\deg (x)=\deg (y)=1$
,
$\sigma _b(x)=x$
and
$\sigma _c(y)=y$
.
Proof.
(1) Consider the
$1$
-cocycle
$z\colon G_b\to \operatorname {PGL}_p(F_b)$
given by
\begin{align*}\sigma _b\mapsto \left[\begin{array}{l@{\quad}l@{\quad}l@{\quad}l@{\quad}l} 0 & 0 & \ldots & 0 & c \\ 1 & 0 & \ldots & 0 & 0 \\ 0 & 1 & \ldots & 0 & 0 \\ \vdots & \vdots & \ddots & \vdots & \vdots \\ 0 & 0 & \ldots & 1 & 0 \\ \end{array} \right]. \end{align*}
By [Reference Gille and SzamuelyGS17, Construction 2.5.1], the class
$[z]\in H^1(G_b,\operatorname {PGL}_p(F_b))$
coincides with the class of the degree-
$p$
central simple algebra over
$F$
with Brauer class
$(b,c)$
, and hence with the class of the associated Severi–Brauer variety
$X$
. It follows that we have a
$G_b$
-equivariant isomorphism
$X_b\simeq \mathbb P^{p-1}_b$
, where
$G_b$
acts on
$X_b$
via its action on
$F_b$
, and on
$\mathbb P^{p-1}_b$
via the cocycle
$z$
. This proves (1).
(2) By a theorem of Lichtenbaum [Reference Gille and SzamuelyGS17, Theorem 5.4.10], we have an exact sequence
\begin{equation*}\operatorname {Pic}(X)\xrightarrow {\deg } \mathbb Z\xrightarrow {\delta }\operatorname {Br}(F),\end{equation*}
where
$\delta (1)=(b,c)$
. Since
$(b,c)$
has exponent
$p$
, we conclude that the image of
$\deg$
is equal to
$p\mathbb Z$
.
(3) Let
$G_{b,c}:= \operatorname {Gal}(F_{b,c}/F)=\langle {\sigma _b,\sigma _c}\rangle$
. By (1), there is a
$G_{b,c}$
-equivariant isomorphism
$f\colon \mathbb P^{p-1}_{b,c}\to X_{b,c}$
, where
$G_{b,c}$
acts on
$X_{b,c}$
via its action on
$F_{b,c}$
, the action of
$\sigma _c$
on
$\mathbb P^{p-1}_{b,c}$
is trivial and the action of
$\sigma _b$
on
$\mathbb P^{p-1}_{b,c}$
is determined by
\begin{equation*}\sigma _b^*(s_1)=cs_p,\quad \sigma _b^*(s_i)=s_{i-1}\quad (i=2,\ldots ,p).\end{equation*}
Consider the linear form
$l:={{\sum }}_{i=1}^{p} c^{i/p}\cdot s_i$
on
$\mathbb P^{p-1}_{b,c}$
and set
$w':= l/s_p\in F_{b,c}(\mathbb P^{p-1})^\times$
. We have
$\sigma _b^*(l)=c^{1/p}\cdot l$
, and hence
$(\sigma _b-1)w'=c^{1/p}\cdot (s_p/s_{p-1})$
. It follows that
$(\sigma _c-1)(\sigma _b-1)w'=\xi$
. Let
$x',y'\in \operatorname {Div}(\mathbb P^{p-1}_{b,c})$
be the classes of the linear subspaces of
$\mathbb P^{p-1}_{b,c}$
given by
$l=0$
and
$s_p=0$
, respectively. Then
\begin{equation*}\operatorname {div}(w')=x'-y',\quad \sigma _b(x')=x',\quad \sigma _c(y')=y'.\end{equation*}
Define
\begin{equation*}w:= w'\circ f^{-1}\in F_{b,c}(X)^\times ,\quad x':= f_*(x)\in (X_{b,c})^{(1)},\quad y':= f_*(y)\in (X_{b,c})^{(1)}.\end{equation*}
Then
$w,x,y$
satisfy the conclusion of (3).
Lemma 4.2.
Let
$a,b,c,d\in F^\times$
. The complex of tori
\begin{equation*}R_{a,c}({\mathbb G}_{\operatorname {m}})\times R_{b,d}({\mathbb G}_{\operatorname {m}})\xrightarrow {\varphi }R_{b,c}({\mathbb G}_{\operatorname {m}})\xrightarrow {\psi } R_{b,c}({\mathbb G}_{\operatorname {m}}),\end{equation*}
where
$\varphi (u,v):= N_a(u)N_d(v)$
and
$\psi (z)=(\sigma _b-1)(\sigma _c-1)z$
, is exact. Furthermore, the torus
$\operatorname {Im}({\varphi })=\operatorname {Ker}(\psi )$
has dimension
$2p-1$
.
Proof. By Lemma 3.8, we have an exact sequence
\begin{equation*}R_c({\mathbb G}_{\operatorname {m}})\times R_b({\mathbb G}_{\operatorname {m}})\xrightarrow {\varphi '} R_{b,c}({\mathbb G}_{\operatorname {m}})\xrightarrow {\psi } R_{b,c}({\mathbb G}_{\operatorname {m}}),\end{equation*}
where
$\varphi '(x,y)=xy$
. The homomorphism
$\varphi$
factors as
\begin{equation*}R_{a,c}({\mathbb G}_{\operatorname {m}})\times R_{b,d}({\mathbb G}_{\operatorname {m}})\xrightarrow {N_a\times N_d}R_c({\mathbb G}_{\operatorname {m}})\times R_b({\mathbb G}_{\operatorname {m}})\xrightarrow {\varphi '} R_{b,c}({\mathbb G}_{\operatorname {m}}).\end{equation*}
Since the homomorphisms
$N_a$
and
$N_d$
are surjective, so is
$N_a\times N_d$
. We conclude that
$\operatorname {Im}(\varphi )=\operatorname {Im}(\varphi ')=\operatorname {Ker}(\psi )$
, as desired. Finally, it is immediate to see that
$\operatorname {Ker}(\varphi ')={\mathbb G}_{\operatorname {m}}$
, embedded anti-diagonally in
$R_c({\mathbb G}_{\operatorname {m}})\times R_b({\mathbb G}_{\operatorname {m}})$
. Thus,
\begin{equation*}{\dim }(\operatorname {Im}(\varphi ))={\dim }(\operatorname {Im}(\varphi '))=2p-{\dim }(\operatorname {Ker}(\varphi '))=2p-1.\end{equation*}
Let
$a,b,c,d\in F^\times$
, and consider the complex of tori of Lemma 4.2. We define the following groups of multiplicative type over
$F$
:
\begin{equation*}P:= R_{a,c}({\mathbb G}_{\operatorname {m}})\times R_{b,d}({\mathbb G}_{\operatorname {m}}),\quad S:= \operatorname {Ker}(\psi )=\operatorname {Im}(\varphi ),\quad T:= \operatorname {Ker}(\varphi )\subset P.\end{equation*}
By Lemma 4.2, we get a short exact sequence
\begin{align} 1\to T\xrightarrow {\iota } P\xrightarrow {\pi } S\to 1, \end{align}
where
$\iota$
is the inclusion map and
$\pi$
is induced by
$\varphi$
.
Lemma 4.3.
The groups of multiplicative type
$T$
,
$P$
and
$S$
are tori.
Proof.
It is clear that
$P$
and
$S$
are tori. We now prove that
$T$
is a torus. Consider the subgroup
$Q\subset R_{a,c}({\mathbb G}_{\operatorname {m}})$
, which makes the following commutative square cartesian.
Here the bottom horizontal map is the obvious inclusion. It follows that
$Q$
is an
$R_c(R^{(1)}_a({\mathbb G}_{\operatorname {m}}))$
-torsor over
${\mathbb G}_{\operatorname {m}}$
, and hence it is smooth and connected. Therefore,
$Q$
is a torus.
The image of the projection
$T \stackrel {\iota }{\hookrightarrow } P\to R_{a,c}({\mathbb G}_{\operatorname {m}})$
is contained in the torus
$Q$
. Moreover, the kernel
$U$
of the projection is
$R_b(R^{(1)}_{F_{b,d}/F_b}({\mathbb G}_{\operatorname {m}}))$
, and hence it is also a torus. We have an exact sequence
\begin{equation*}1\to U\to T\to Q.\end{equation*}
We have
${\dim }(U) = p(p-1)$
, and we see from the cartesian square (4.2) that
${\dim } (Q) = p^2 - p +1$
. By Lemma 4.2, we have
${\dim }(S)=2p-1$
. From (4.1), we deduce that
\begin{equation*}{\dim } (T) = {\dim }(P) - {\dim }(S) = 2p^2 -(2p-1)=2p^2-2p+1.\end{equation*}
Therefore,
${\dim } (T) = {\dim } (U) + {\dim } (Q)$
, and so the sequence
\begin{equation*}1 \to U \to T \to Q \to 1\end{equation*}
is exact. As
$U$
and
$Q$
are tori, so is
$T$
.
Proposition 4.4.
Let
$p$
be a prime, let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
, and let
$a,b,c,d\in F^\times$
. Suppose that
$(a,b)=(b,c)=(c,d)=0$
in
$\operatorname {Br}(F)$
, and let
$w\in F_{b,c}^\times$
be such that
$(\sigma _b-1)(\sigma _c-1)w = \zeta$
. Let
$T$
and
$P$
be the tori appearing in (
4.1
), and let
$E_w\subset P$
be the
$T$
-torsor given by the equation
$N_a(u)N_d(v)=w^p$
. Then the mod
$p$
Massey product
$\langle {a,b,c,d}\rangle$
is defined over
$F$
if and only if
$E_w$
is trivial.
The construction of
$E_w$
is functorial in
$F$
. Therefore, for every field extension
$K/F$
, the mod
$p$
Massey product
$\langle {a,b,c,d}\rangle$
is defined over
$K$
if and only if
$E_w$
is split by
$K$
. We may thus call
$E_w$
a generic variety for the property ‘the Massey product
$\langle {a,b,c,d}\rangle$
is defined’.
Proof.
Suppose that the Massey product
$\langle {a,b,c,d}\rangle$
is defined over
$F$
. By Proposition 3.9, there exist
$u\in F_{a,c}^\times$
,
$v\in F_{b,d}^\times$
such that
$N_a(u)N_d(v) = w^p$
. This means precisely that
$E_w\subset P$
has the
$F$
-point
$(u,v)$
. Thus, the
$T$
-torsor
$E_w$
is trivial.
Conversely, suppose that the
$T$
-torsor
$E_w$
is trivial and let
$(u,v)$
be an
$F$
-point of
$E_w$
. Then we have
$N_a(u)N_d(v) = w^p$
and, by assumption, we also have
$(\sigma _b-1)(\sigma _c-1)w = \zeta$
. Proposition 3.7 now implies that the Massey product
$\langle {a,b,c,d}\rangle$
is defined over
$F$
.
Corollary 4.5.
Let
$p$
be a prime, let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
, and let
$a,b,c,d\in F^\times$
be such that
$(a,b)=(c,d)=0$
in
$\operatorname{Br}(F)$
. Let
$X$
be the Severi–Brauer variety of
$(b,c)$
over
$F$
, fix
$w\in F_{b,c}(X)^\times$
as in Lemma 4.1(3) and let
$E_w\subset P_{F(X)}$
be the
$T_{F(X)}$
-torsor given by the equation
$N_a(u)N_d(v)=w^p$
.
The Massey product
$\langle {a,b,c,d}\rangle$
is defined over
$F(X)$
if and only if
$E_w$
is trivial over
$F(X)$
.
Proof.
This is a special case of Proposition 4.4, applied over the ground field
$F(X)$
.
5. Proof of Theorem 1.3
Let
$p$
be a prime and let
$F$
be a field of characteristic different from
$p$
and containing a primitive
$p$
th root of unity
$\zeta$
. Let
$a,b,c,d\in F^\times$
be such that their cosets in
$F^\times /F^{\times p}$
are
${\mathbb F}_p$
-linearly independent. Consider the field
$K:= F_{a,b,c,d}$
, and write
$G=\operatorname {Gal}(K/F)=\langle {\sigma _a,\sigma _b,\sigma _c,\sigma _d}\rangle$
as in § 2.1. We set
$N_a:= {{\sum }}_{j=0}^{p-1}\sigma _a^{{\kern1.1pt}j}\in \mathbb Z[G]$
. For every subgroup
$H$
of
$G$
, we also write
$N_a$
for the image of
$N_a\in \mathbb Z[G]$
under the canonical map
$\mathbb Z[G]\to \mathbb Z[G/H]$
. We define
$N_b$
,
$N_c$
and
$N_d$
in a similar way.
Let
\begin{equation*}1\to T\xrightarrow {\iota } P\xrightarrow {\pi } S\to 1 \end{equation*}
be the short exact sequence of
$F$
-tori (4.1). It induces a short exact sequence of cocharacter
$G$
-lattices
\begin{equation*}0\to T_*\xrightarrow {\iota _*} P_*\xrightarrow {\pi _*} S_*\to 1.\end{equation*}
By definition of
$P$
and
$S$
,
\begin{equation*}P_*=\mathbb Z[G/\langle \sigma _b,\sigma _d\rangle ]\oplus \mathbb Z[G/\langle \sigma _a,\sigma _c\rangle ],\quad S_*=\langle N_b,N_c\rangle \subset \mathbb Z[G/\langle \sigma _a,\sigma _d\rangle ].\end{equation*}
Let
$X$
be the Severi–Brauer variety associated to
$(b,c)\in \operatorname {Br}(F)$
. Since
$X_K\simeq \mathbb P^{p-1}_K$
, the degree map
$\operatorname {Pic}(X_K)\to \mathbb Z$
is an isomorphism, and so the map
$\operatorname {Div}(X_K)\to \operatorname {Pic}(X_K)$
is identified with the degree map
$\deg \colon \operatorname {Div}(X_K)\to \mathbb Z$
. Thus, the sequence (B.2) for the torus
$T$
takes the form
\begin{align} 1\to T(K) \to T(K(X))\xrightarrow {\operatorname {div}}\operatorname {Div}(X_K)\otimes T_*\xrightarrow {\deg } T_*\to 0, \end{align}
where
$T_*$
denotes the cocharacter lattice of
$T$
.
Lemma 5.1.
-
(1) We have
$(T_*)^G=\mathbb Z\cdot \eta$
, where
$\iota _*(\eta )=(N_a N_c,-N_b N_d)$
in
$(P_*)^G$
. -
(2) If
$(b,c)\neq 0$
in
$\operatorname {Br}(F)$
, the image of
$\deg \colon (\operatorname {Div}(X_{b,c})\otimes T_*)^G\to (T_*)^G$
is equal to
$p(T_*)^G$
.
Proof.
(1) The free
$\mathbb Z$
-module
$(P_*)^G$
has a basis consisting of the elements
$(N_aN_c,0)$
and
$(0,N_bN_d)$
. The map
$\pi _*\colon P_* \to S_*\subset \mathbb Z[G/\langle {\sigma _a,\sigma _d}\rangle ]$
takes
$(1, 0)$
to
$N_b$
and
$(0, 1)$
to
$N_c$
. It follows that
$\operatorname {Ker}(\pi _*)^G$
is generated by
$(N_aN_c, -N_bN_d)$
.
(2) By Lemma 4.1(2), the image of the composition
\begin{equation*}\operatorname {Div}(X)\otimes T_*^G=(\operatorname {Div}(X)\otimes T_*)^G\to (\operatorname {Div}(X_{b,c})\otimes T_*)^G\xrightarrow {\operatorname {\deg }} (T_*)^G \end{equation*}
is equal to
$p(T_*)^G$
. Thus, the image of the degree map contains
$p(T_*)^G$
.
We now show that the image of the degree map is contained in
$p(T_*)^G$
.
For every
$x\in X^{(1)}$
, pick
$x'\in (X_{b,c})^{(1)}$
lying over
$x$
, and write
$H_x$
for the
$G$
-stabilizer of
$x'$
. The injective homomorphisms of
$G$
-modules
\begin{equation*}j_x\colon \mathbb Z[G/H_x]\hookrightarrow \operatorname {Div}(X_{b,c}),\quad gH_x\mapsto g(x'), \end{equation*}
yield an isomorphism of
$G$
-modules
\begin{equation*}\oplus _{x\in X^{(1)}}j_x\colon \oplus _{x\in X^{(1)}}\mathbb Z[G/H_x]\xrightarrow {\sim } \operatorname {Div}(X_{b,c}).\end{equation*}
To conclude, it suffices to show that the image of
\begin{align} (T_*)^{H_x}=(\mathbb Z[G/H_x]\otimes T_*)^G\to (\operatorname {Div}(X_{b,c})\otimes T_*)^G\xrightarrow {\deg } (T_*)^G \end{align}
is contained in
$p(T_*)^G$
for all
$x\in X^{(1)}$
. Set
$H:=H_x$
.
The composition (5.2) takes a cocharacter
$q\in (T_*)^{H}$
to
\begin{equation*}\deg \biggl(\mathop {{\sum }}\limits _{gH\in G/H} gx'\otimes gq \biggr)=\deg (x')\cdot N_{G/H}(q).\end{equation*}
Thus, (5.2) coincides with the norm map
$N_{G/H}$
times the degree of
$x'$
.
Suppose that
$G=H$
. Then
$\deg (x')=\deg (x)$
and, since
$(b,c)\neq 0$
, the degree of
$x$
is divisible by
$p$
by Lemma 4.1(2).
Suppose that
$G\neq H$
. Then either
$\langle \sigma _a,\sigma _c\rangle$
or
$\langle \sigma _b,\sigma _d\rangle$
is not contained in
$H$
. Suppose that
$\langle \sigma _b,\sigma _d\rangle$
is not contained in
$H$
and let
$N$
be the subgroup generated by
$H,\sigma _b,\sigma _d$
. Note that
$H$
is a proper subgroup of
$N$
.
The norm map
$N_{G/H}:(T_*)^H\to (T_*)^G$
is the composition of the two norm maps
\begin{equation*} (T_*)^H\xrightarrow {N_{N/H}} (T_*)^N\xrightarrow {N_{G/N}} (T_*)^G. \end{equation*}
Since
$\mathbb Z[G/\langle {\sigma _b,\sigma _d}\rangle ]^H=\mathbb Z[G/\langle {\sigma _b,\sigma _d}\rangle ]^N$
, the norm map
$(T_*)^H\to (T_*)^N$
is multiplication by
$[N:H]\in p\mathbb Z$
on the first component of
$T_*$
with respect to the inclusion
$\iota _*$
of
$T_*$
into
$P_*=\mathbb Z[G/\langle {\sigma _b,\sigma _d}\rangle ]\oplus \mathbb Z[G/\langle {\sigma _a,\sigma _c}\rangle ]$
.
By Lemma 5.1(1),
$(T_*)^G=\mathbb Z\cdot \eta$
, where
$\iota _*(\eta )=(N_a N_c,-N_b N_d)$
in
$(P_*)^G$
. Since
$N_a N_c$
is not divisible by
$p$
in
$\mathbb Z[G/\langle {\sigma _b,\sigma _d}\rangle ]$
, the image of (5.2) is contained in
$p\mathbb Z\cdot \eta =p(T_*)^G$
, as desired. The proof in the case when
$\langle{\sigma_a,\sigma_c}\rangle $
is not contained in H is entirely analogous.
We write
\begin{equation*}\overline {\eta } \in \operatorname {Coker}[(\operatorname {Div}(X_{b,c})\otimes T_*)^G\xrightarrow {\deg } (T_*)^G] \end{equation*}
for the coset of the generator
$\eta \in (T_*)^G$
appearing in Lemma 5.1(1). If
$(b,c)\neq 0$
, then we have
$\overline {\eta }\neq 0$
by Lemma 5.1(2). We consider the subgroup of unramified torsors
\begin{equation*}H^1(G,T(K(X)))_{\operatorname {nr}}:= \operatorname {Ker}[H^1(G,T(K(X)))\xrightarrow {\operatorname {div}}H^1(G,\operatorname {Div}(X_K\otimes T_*))]\end{equation*}
and the homomorphism
\begin{equation*}\theta \colon H^1(G,T(K(X)))_{\operatorname {nr}}\to \operatorname {Coker}[(\operatorname {Div}(X_K)\otimes T_*)^G\xrightarrow {\deg } (T_*)^G],\end{equation*}
which are defined in (B.3).
Lemma 5.2.
Let
$b,c\in F^\times$
be such that
$(b,c)\neq 0$
in
$\operatorname {Br}(F)$
and let
$w\in F_{b,c}(X)^{\times }$
be such that
$(\sigma _b-1)(\sigma _c-1)w=\zeta$
and
$\operatorname {div}(w)=x-y$
, where
$\deg (x)=\deg (y)=1$
and
$\sigma _b(x)=x$
and
$\sigma _c(y)=y$
. Let
$E_w\subset P_{F(X)}$
be the
$T_{F(X)}$
-torsor given by the equation
$N_a(u)N_d(v)=w^p$
, and write
$[E_w]$
for the class of
$E_w$
in
$H^1(G,T(K(X)))$
.
-
(1) We have
$[E_w]\in H^1(G,T(K(X)))_{\operatorname {nr}}$
. -
(2) Let
$\theta$
be the homomorphism of (
B.3
). We have
$\theta ([E_w])=-\overline {\eta }\neq 0$
.
Proof.
The
$F$
-tori
$T$
,
$P$
and
$S$
of (4.1) are split by
$K=F_{a,b,c,d}$
. Therefore, we may consider diagram (B.6) for the short exact sequence (4.1), the splitting field
$K/F$
and the Severi–Brauer variety
$X$
of
$(b,c)$
over
$F$
.
Since
$(\sigma _b-1)(\sigma _c-1)w^p=1$
, we have
$w^p\in S(F(X))$
. The image of
$w^p$
under
$\partial$
is equal to
$[E_w]\in H^1(G,T(K(X)))$
.
Let
$H\subset G$
be the subgroup generated by
$\sigma _a$
and
$\sigma _d$
. The canonical isomorphism
\begin{equation*} \operatorname {Div}(X_{b,c})=\operatorname {Div}(X_K)^H=(\operatorname {Div}(X_K)\otimes \mathbb Z[G/H])^G \end{equation*}
sends the divisor
$\operatorname {div}(w)=x-y$
to
$ \sum_{i,j=0}^{p-1} \sigma _b^i\sigma _c^{{\kern1.1pt}j} (x-y)\otimes \sigma _b^i\sigma _c^{{\kern1.1pt}j}$
. Therefore, the element
$\operatorname {div}(w^p)$
in
$(\operatorname {Div}(X_K)\otimes S_*)^G\subset (\operatorname {Div}(X_K)\otimes \mathbb Z[G/H])^G$
is equal to
\begin{equation*} e:=p\mathop {{\sum }}\limits _{i,j=0}^{p-1}(\sigma _b^i\sigma _c^{{\kern1.1pt}j}(x-y)\otimes \sigma _b^i\sigma _c^{{\kern1.1pt}j})= p\mathop {{\sum }}\limits _{j=0}^{p-1}(\sigma _c^{{\kern1.1pt}j} x \otimes \sigma _c^{{\kern1.1pt}j} N_b)-p\mathop {{\sum }}\limits _{i=0}^{p-1}(\sigma _b^i y \otimes \sigma _b^i N_c). \end{equation*}
Since
$S_*$
is the G-sublattice of
$\mathbb Z[G/\langle \sigma _a,\sigma _d\rangle ]$
generated by
$N_b$
and
$N_c$
, this implies that
$e$
belongs to
$(\operatorname {Div}(X_K)\otimes S_*)^G$
. Then
$e=\pi _*(f)$
, where
\begin{equation*} f:=\mathop {{\sum }}\limits _{j=0}^{p-1}(\sigma _c^{{\kern1.1pt}j} x \otimes \sigma _c^{{\kern1.1pt}j} N_a)-\mathop {{\sum }}\limits _{i=0}^{p-1}(\sigma _b^i y \otimes \sigma _b^i N_d)\in (\operatorname {Div}(X_K)\otimes P_*)^G. \end{equation*}
It follows that
$\operatorname {div}([E_w])=\partial (e)=\partial (\pi _*(f))=0$
, which proves (1).
Moreover, since
$\deg (x)=\deg (y)=1$
, we have
\begin{equation*} \deg (f)=(N_a N_c, - N_b N_d)=\iota _*(\eta )\quad \text {in $(P_*)^G$.} \end{equation*}
In view of (B.7), this implies that
$\theta ([E_w])=-\overline {\eta }$
. We know from Lemma 5.1(2) that
$\overline {\eta }\neq 0$
. This completes the proof of (2).
Proof of Theorem
1.3
. Replacing
$F$
by a finite extension, if necessary, we may suppose that
$F$
contains a primitive
$p$
th root of unity
$\zeta$
. Let
$E:= F(x,y)$
, where
$x$
and
$y$
are independent variables over
$F$
, let
$X$
be the Severi–Brauer variety of the degree-
$p$
cyclic algebra
$(x,y)$
over
$E$
and let
$L:= E(X)$
. Consider the following elements of
$E^\times$
:
\begin{equation*}a:= 1-x,\quad b:= x,\quad c:= y,\quad d:= 1-y.\end{equation*}
We have
$(a,b)=(c,d)=0$
in
$\operatorname {Br}(E)$
by the Steinberg relations [Reference Serre and GreenbergSer79, Chapter XIV, Proposition 4(iv)], and hence
$(a,b)=(b,c)=0$
in
$\operatorname {Br}(L)$
. Moreover,
$(b,c)\neq 0$
in
$\operatorname {Br}(E)$
because the residue of
$(b,c)$
along
$x=0$
is non-zero, whereas
$(b,c)=0$
in
$\operatorname {Br}(L)$
by [Reference Gille and SzamuelyGS17, Theorem 5.4.1]. Thus,
$(a,b)=(b,c)=(c,d)=0$
in
$\operatorname {Br}(L)$
.
Consider the sequence of tori (4.1) over the ground field
$E$
associated to the scalars
$a,b,c,d\in E^\times$
chosen above:
\begin{equation*}1\to T\to P\to S\to 1.\end{equation*}
Let
$w\in L_{b,c}(X)$
be as in Lemma 4.1(3), and let
$E_w\subset P_L$
be the
$T_L$
-torsor given by the equation
$N_a(u)N_d(v)=w^p$
. By Lemma 5.2(2), the torsor
$E_w$
is non-trivial over
$L$
. Now Corollary 4.5 implies that the Massey product
$\langle a,b,c,d\rangle$
is not defined over
$L$
. In particular, by Lemma 2.3, the differential graded ring
$C^{*}(\Gamma _L,\mathbb Z/p\mathbb Z)$
is not formal.
Appendix A. Homological algebra
Let
$G$
be a profinite group, and let
\begin{align} 0\to A_0\xrightarrow {\alpha _0} A_1\xrightarrow {\alpha _1} A_2\xrightarrow {\alpha _2} A_3\to 0 \end{align}
be an exact sequence of discrete
$G$
-modules. We break (A.1) into two short exact sequences
\begin{equation*}0\to A_0\xrightarrow {\alpha _0} A_1\to A\to 0,\end{equation*}
\begin{equation*}0\to A\to A_2\xrightarrow {\alpha _2} A_3\to 0.\end{equation*}
We obtain a homomorphism
\begin{align} \theta \colon \operatorname {Ker}[H^1(G,A_1)\xrightarrow {\alpha _1} H^1(G,A_2)]\to \operatorname {Coker}[A_2^G\xrightarrow {\alpha _2} A_3^G], \end{align}
which is defined as the composition of the map
\begin{equation*}\operatorname {Ker}[H^1(G,A_1)\xrightarrow {\alpha _1} H^1(G,A_2)]\to \operatorname {Ker}[H^1(G,A)\to H^1(G,A_2)], \end{equation*}
and the inverse of the isomorphism
\begin{align} \operatorname {Coker}[A_2^G\xrightarrow {\alpha _2} A_3^G]\xrightarrow {\sim } \operatorname {Ker}[H^1(G,A)\to H^1(G,A_2)], \end{align}
which is induced by the connecting homomorphism
$A_3^G\to H^1(G,A)$
.
Lemma A.1. We have an exact sequence
\begin{align*} H^1(G,A_0)\xrightarrow {\alpha _0} \operatorname {Ker}[H^1(G,A_1)\xrightarrow {\alpha _1}H^1(G,A_2)]\xrightarrow {\theta } \operatorname {Coker}[A_2^G\to A_3^G]\to H^2(G,A_0), \end{align*}
where the last map is defined as the composition of (A.3) and the connecting homomorphism
$H^1(G,A)\to H^2(G,A_0)$
.
Proof.
The proof follows from the definition of
$\theta$
and the exactness of (A.1).
Consider a commutative diagram of discrete
$G$
-modules with exact rows and columns.
It yields a commutative diagram of abelian groups where the columns are exact and the rows are complexes.
Suppose that the connecting homomorphism
$\partial _1\colon C_1^G\to H^1(G,A_1)$
is surjective. We define a function
\begin{equation*}\theta '\colon \operatorname {Ker}[H^1(G,A_1)\xrightarrow {\alpha _1} H^1(G,A_2)]\to \operatorname {Coker}(A_2^G\xrightarrow {\alpha _2} A_3^G) \end{equation*}
as follows. Let
$z\in H^1(G,A_1)$
such that
$\alpha _1(z)=0$
in
$H^1(G,A_2)$
. By assumption, there exists
$c_1\in C_1^G$
such that
$\partial _1(c_1)=z$
. By the exactness of the second column, there exists
$b_2\in B_2^G$
such that
$\pi _2(b_2)=\gamma _1(c_1)$
. By the exactness of the third column and the injectivity of
$\iota _3$
, there exists a unique element
$a_3\in A_3^G$
such that
$\beta _2(b_2)=\iota _3(a_3)$
. We set
\begin{equation*}\theta '(z):= a_3+\alpha _2(A_2^G).\end{equation*}
A diagram chase shows that
$\theta '$
is a well-defined homomorphism.
Lemma A.2.
Let
$G$
be a profinite group, and suppose that we are given an exact sequence (
A.1
) and a commutative diagram (
A.4
) such that the connecting homomorphism
$\partial _1\colon C_1^G\to H^1(G,A_1)$
is surjective. Then
$\theta =-\theta '$
.
Proof.
Let
$z\in H^1(G,A_1)$
be such that
$\alpha _1(z)=0$
in
$H^1(G,A_2)$
. Since the map
$\partial _1\colon C_1^G\to H^1(G,A_1)$
is surjective, there exists
$c_1\in C_1^G$
such that
$\partial _1(c_1)=z$
. Let
$b_1\in B_1$
be such that
$\pi _1(b_1)=c_1$
, and, for all
$g\in G$
, let
$a_{1g}$
be the unique element of
$A_1$
such that
$\iota _1(a_{1g})=gb_1-b_1$
. Then
$\partial _1(c_1)$
is represented by the
$1$
-cocycle
$\left \{a_{1g}\right \}_{g\in G}$
.
Define
$b_2:= \beta _1(b_1)$
and
$c_2:= \gamma _1(c_1)$
, so that
$\pi _2(b_2)=c_2$
. Since
$\alpha _1(z)=0$
is represented by the cocycle
$\left \{\alpha _1(a_{1g})\right \}_{g\in G}$
, we deduce that there exists
$a_2\in A_2$
such that
$\alpha _1(a_{1g})=ga_2-a_2$
for all
$g\in G$
. It follows that
$gb_2-b_2=\iota _2(ga_2-a_2)$
for all
$g\in G$
, that is,
$b_2-\iota _2(a_2)$
belongs to
$B_2^G$
. Moreover,
\begin{equation*}\pi _2(b_2-\iota _2(a_2))=\pi _2(b_2)=\gamma _1(c_1).\end{equation*}
Finally,
\begin{equation*}\beta _2(b_2-\iota _2(a_2))=\beta _2(\beta _1(b_1))-\iota _3(\alpha _2(a_2))=\iota _3(-\alpha _2(a_2)).\end{equation*}
By definition,
$\theta '(z)=-\alpha _2(a_2)+\alpha _2(A_2^G)$
. Observe that
$\alpha _2(a_2)$
belongs to
$A_3^G$
because, for every
$g\in G$
,
\begin{equation*}g\alpha _2(a_2)-\alpha _2(a_2)=\alpha _2(ga_2-a_2)=\alpha _2(\alpha _1(a_{1g}))=0.\end{equation*}
For all
$g\in G$
, let
$a_g\in A$
be the image of
$a_{1g}$
. The homomorphism
\begin{equation*}\operatorname {Ker}[H^1(G,A_1)\xrightarrow {\alpha _1} H^1(G,A_2)]\to \operatorname {Ker}[H^1(G,A)\to H^1(G,A_2)], \end{equation*}
induced by the map
$A_1\to A$
, sends the class of
$\left \{a_{1g}\right \}_{g\in G}$
to the class of
$\left \{a_g\right \}_{g\in G}$
.
The element
$a_2\in A_2$
is a lift of
$\alpha _2(a_2)$
. As
$ga_2-a_2=\alpha _1(a_{1g})$
for all
$g\in G$
, the injective map
$A\to A_2$
sends
$a_g$
to
$ga_2-a_2$
for all
$g\in G$
. Therefore, the connecting map
$A_3^G\to H^1(G,A)$
sends
$\alpha _2(a_2)$
to the class of
$\left \{a_g\right \}_{g\in G}$
. It follows that the isomorphism
\begin{equation*}\operatorname {Coker}[A_2^G\xrightarrow {\alpha _2} A_3^G]\xrightarrow {\sim } \operatorname {Ker}[H^1(G,A)\to H^1(G,A_2)], \end{equation*}
induced by
$A_3^G\to H^1(G,A)$
, sends
$\alpha _2(a_2)+\alpha _2(A_2^G)$
to the class of
$\left \{a_g\right \}_{g\in G}$
. By the definition of
$\theta$
, we conclude that
$\theta (z)=\alpha _2(a_2)+\alpha _2(A_2^G)=-\theta '(z)$
.
Appendix B. Unramified torsors under tori
Let
$F$
be a field, let
$X$
be a smooth projective geometrically connected
$F$
-variety, let
$K$
be a Galois extension of
$F$
(possibly of infinite degree over
$F$
) and let
$G:= \operatorname {Gal}(K/F)$
. We have an exact sequence of discrete
$G$
-modules
\begin{align} 1\to K^\times \to K(X)^\times \xrightarrow {\operatorname {div}} \operatorname {Div}(X_K)\xrightarrow {\lambda } \operatorname {Pic}(X_K)\to 0, \end{align}
where
$\operatorname {div}$
takes a non-zero rational function
$f\in K(X)^\times$
to its divisor and
$\lambda$
takes a divisor on
$X_K$
to its class in
$\operatorname {Pic}(X_K)$
.
Let
$T$
be an
$F$
-torus split by
$K$
. Write
$T_*$
for the cocharacter lattice of
$T$
: it is a finitely generated
$\mathbb Z$
-free
$G$
-module. Tensoring (B.1) with
$T_*$
, we obtain an exact sequence of
$G$
-modules
\begin{align} 1\to T(K) \to T(K(X))\xrightarrow {\operatorname {div}} \operatorname {Div}(X_K)\otimes T_*\xrightarrow {\lambda } \operatorname {Pic}(X_K)\otimes T_*\to 0, \end{align}
where we have used the fact that
$K^\times \otimes T_*=T(K)$
.
We define the subgroup of unramified torsors
\begin{equation*}H^1(G,T(K(X)))_{\operatorname {nr}}:= \operatorname {Ker}[H^1(G,T(K(X)))\xrightarrow {\operatorname {div}}H^1(G,\operatorname {Div}(X_K\otimes T_*))].\end{equation*}
The sequence (B.1) is a special case of (A.1). In this case, the map
$\theta$
of (A.1) takes the form
\begin{align} \theta \colon H^1(G,T(K(X)))_{\operatorname {nr}}\to \operatorname {Coker}[(\operatorname {Div}(X_K)\otimes T_*)^G\xrightarrow {\lambda }(\operatorname {Pic}(X_K)\otimes T_*)^G]. \end{align}
Proposition B.1. We have an exact sequence
\begin{align*} H^1(G, T(K)) \to H^1(G, T(K(X)))_{\operatorname {nr}} & \xrightarrow {\theta } \operatorname {Coker} [(\operatorname {Div}(X_K)\otimes T_*)^G \xrightarrow {\lambda }(\operatorname {Pic}(X_K)\otimes T_*)^G ] \\ &\to H^2(G, T(K)), \end{align*}
where the first map and the last map are induced by (B.2).
Proof. This is a special case of Lemma A.1.
By Lemma A.2, the map
$\theta$
may be computed as follows. Let
\begin{align} 1\to T\xrightarrow {\iota } P\xrightarrow {\pi } S\to 1 \end{align}
be a short exact sequence of
$F$
-tori split by
$K$
such that
$P$
is a quasi-trivial torus. Passing to cocharacter lattices, we obtain a short exact sequence of
$G$
-modules
\begin{align} 0\to T_*\xrightarrow {\iota _*} P_*\xrightarrow {\pi _*} S_*\to 0. \end{align}
We tensor (B.1) with
$T_*$
,
$P_*$
and
$S_*$
, respectively, and pass to group cohomology to obtain the following commutative diagram, where the columns are exact and the rows are complexes.
Note that
$\operatorname {Gal}(K(X)/F(X))=G$
. Therefore,
$H^1(G,P(K(X)))$
is trivial, and hence
$\partial \colon S(F(X))\to H^1(G,T(K(X)))$
is surjective.
Let
$\tau \in H^1(G, T(K(X)))_{\operatorname {nr}}$
and choose
$\sigma \in S(F(X))$
such that
$\partial (\sigma )=\tau$
. Then pick
$\rho \in (\operatorname {Div}(X_K)\otimes P_*)^G$
such that
$\pi _*(\rho )=\operatorname {div}(\sigma )$
, and let
$t$
be the unique element in
$(\operatorname {Pic}(X_K)\otimes T_*)^G$
such that
$\lambda (\rho )=\iota _*(t)$
. Lemma A.2 implies that
\begin{align} \theta (\tau )=-t. \end{align}
Finally, suppose that
$K=F_s$
is a separable closure of
$F$
, so that
$G=\Gamma _F$
, and write
$X_s$
for
$X\times _FF_s$
. The exact sequence (B.2) for
$K=F_s$
takes the form
\begin{align} 1\to T(F_s) \to T(F_s(X))\xrightarrow {\operatorname {div}} \operatorname {Div}(X_s)\otimes T_*\xrightarrow {\lambda } \operatorname {Pic}(X_s)\otimes T_*\to 0. \end{align}
We have the inflation–restriction sequence
\begin{equation*}0\to H^1(F,T(F_s(X)))\xrightarrow {\operatorname {Inf}}H^1(F(X),T)\xrightarrow {\operatorname {Res}}H^1(F_s(X),T).\end{equation*}
Since
$T$
is defined over
$F$
, it is split by
$F_s$
, and hence by Hilbert’s Theorem 90 we have
$H^1(F_s(X),T)$
= 0. Thus, the inflation map
$H^1(F,T(F_s(X)))\to H^1(F(X),T)$
is an isomorphism. We identify
$H^1(F,T(F_s(X)))$
with
$H^1(F(X),T)$
via the inflation map. If we define
\begin{equation*}H^1(F(X),T)_{\operatorname {nr}}:= \operatorname {Ker}[H^1(F(X),T)\xrightarrow {\operatorname {div}}H^1(F,\operatorname {Div}(X_s)\otimes T_*)],\end{equation*}
the map
$\theta$
of (A.2) takes the form
\begin{equation}\theta \colon H^1(F(X),T)_{\operatorname {nr}}\to \operatorname {Coker}[(\operatorname {Div}(X_s)\otimes T_*)^{\Gamma _F}\to (\operatorname {Pic}(X_s)\otimes T_*)^{\Gamma _F}].\end{equation}
Corollary B.2. We have an exact sequence
\begin{equation*} H^1(F, T) \to H^1(F(X), T)_{\operatorname {nr}} \xrightarrow {\theta } \operatorname {Coker} [(\operatorname {Div}(X_s)\otimes T_*)^{\Gamma _F} \xrightarrow {\lambda } (\operatorname {Pic}(X_s)\otimes T_*)^{\Gamma _F}] \to H^2(F, T), \end{equation*}
where the first and last map are induced by (B.8).
Proof. This is a special case of Proposition B.1.
Acknowledgements
We thank the anonymous referee for carefully reading our manuscript and for sending us comments which greatly improved the exposition.
Conflicts of interest
None.
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