1. Introduction
1.1 Statement of results
In this paper, we study the étale cohomology of Hilbert modular varieties, building on the methods introduced for unitary Shimura varieties in [Reference Caraiani and ScholzeCS17, Reference Caraiani and ScholzeCS19].
Let us first discuss a general vanishing conjecture for the cohomology of locally symmetric spaces. Let $G/\mathbb {Q}$ be a connected reductive group and let $X$ be the symmetric space for $G({\mathbb {R}})$, in the sense of [Reference Borel and SerreBS73]. For a neat compact open subgroup $K\subset G({\mathbb {A}}_f)$, we can consider the associated locally symmetric space $X_K(G)$. Also define the invariantsFootnote 1
A folklore conjecture predicts that the cohomology of the locally symmetric space $X_K(G)$ with ${\mathbb {Z}}_{\ell }$-coefficients vanishes, after imposing an appropriate non-degeneracy condition, outside the range of degrees $[q_0, q_0 +l_0]$ (which is symmetric about $\frac {1}{2}\dim _{{\mathbb {R}}} X$). See, for example, the discussion around [Reference EmertonEme14, Conjecture 3.3] and also [Reference Calegari and GeraghtyCG18, Conjecture B]. As these references explain, this conjecture has important consequences for automorphy lifting theorems and the $p$-adic Langlands programme.
When $F$ is a totally real field and $G:=\mathrm {Res}_{F/{\mathbb {Q}}}\operatorname {GL}_2$, the corresponding locally symmetric spaces are closely related to Hilbert modular varieties, which are (non-compact) Shimura varieties of abelian type. When working with Shimura varieties rather than with locally symmetric spaces, it is more natural to consider $l_0(G^{\mathrm {ad}})$, which is equal to $0$ by the second axiom in the definition of a Shimura datum. In this case, the conjecture mentioned above predicts that the non-degenerate part of the cohomology is concentrated in the middle degree.
To make this more precise, let $K\subset G({\mathbb {A}}_{f})$ be a neat compact open subgroup and let $Sh_K(G)$ be the corresponding Hilbert modular variety. This is a smooth, quasi-projective scheme over ${\mathbb {Q}}$, of dimension $g:=[F:{\mathbb {Q}}]$. Its complex points can be described as
Let $\ell$ be a prime number; we have a spherical Hecke algebra $\mathbb {T}$ defined in § 2.1.2, generated by the standard Hecke operators $T_v, S_v^{\pm 1}$ for $v$ not belonging to a suitable finite set $S$ of places of $F$. The algebra $\mathbb {T}$ acts on the étale cohomology groups $H^i_{(c)}(Sh_K(G), {\mathbb {F}}_{\ell })$.Footnote 2 Take a maximal ideal $\mathfrak {m} \subset \mathbb {T}$ in the support of $H^i_{(c)}(Sh_K(G), {\mathbb {F}}_{\ell })$. It follows from Scholze's work, at least when $\ell >2$, cf. Theorem 2.2.1, that there exists a unique continuous, semisimple Galois representation
where $\Gamma _F$ denotes the absolute Galois group of $F$, which is characterised as follows: for every $v \not \in S$, $\bar {\rho }_\mathfrak {m}$ is unramified at $v$ and the characteristic polynomial of $\bar {\rho }_{\mathfrak {m}}(\mathrm {Frob}_v)$ is equal to $X^2-T_vX+S_vN(v) \pmod {\mathfrak {m}}$.
We say that $\mathfrak {m}$ is non-Eisenstein if $\bar {\rho }_{\mathfrak {m}}$ is absolutely irreducible. The most optimistic vanishing conjecture predicts that the localisation $H^i_{(c)}(Sh_K(G), {\mathbb {F}}_{\ell })_{\mathfrak {m}}$ should be concentrated in the middle degree $i=g$ if $\mathfrak {m}$ is non-Eisenstein. We make significant progress towards this.
Theorem A (see Theorem 7.1.1)
Let $\ell >2$ be a prime and let $\mathfrak {m} \subset \mathbb {T}$ be a maximal ideal in the support of $H^i_{\rm c}(Sh_K(G), {\mathbb {F}}_{\ell })$ or $H^i(Sh_K(G), {\mathbb {F}}_{\ell })$. Assume that the image of $\bar {\rho }_{\mathfrak {m}}$ is not solvable. Then $H^i(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}=H^i_c(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-zero only for $i=g$.
Remark 1.1.1 (i) By Dickson's theorem, cf. [Reference Darmon, Diamond and TaylorDDT97, Theorem 2.47 (b)], the projective image of $\bar {\rho }_{\mathfrak {m}}$ is either conjugate to a subgroup of the upper triangular matrices, or to $\operatorname {PGL}_2({\mathbb {F}}_{\ell ^k})$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, for some $k\geq 1$, or it is isomorphic to one of $D_{2n}$, for some $n\in {\mathbb {Z}}_{> 1}$ prime to $\ell$, $A_4$, $S_4$, or $A_5$. The image of $\bar {\rho }_\mathfrak {m}$ is not solvable if and only if the following condition is satisfied:
(a) if $\ell = 3$, the projective image of $\bar {\rho }_{\mathfrak {m}}$ is isomorphic to $A_5$ or contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_9)$;
(b) if $\ell >3$, the projective image of $\bar {\rho }_{\mathfrak {m}}$ is isomorphic to $A_5$ or contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_{\ell })$.
(ii) If $\mathfrak {m}$ is non-Eisenstein, then $H^i(Sh_K(G), {\mathbb {C}})_\mathfrak {m}$ is concentrated in the middle degree. This follows from the explicit description of the cohomology with complex coefficients of Hilbert modular varieties (see [Reference FreitagFre13, Chapter III]).
(iii) Previously, Dimitrov had obtained a vanishing theorem for the cohomology of Hilbert modular varieties with torsion coefficients in [Reference DimitrovDim09, Theorem 2.3] (see also [Reference DimitrovDim05]), under stronger assumptions. More precisely, Dimitrov proves a theorem for cohomology with coefficients in certain local systems on $Sh_K(G)$. In addition to a large image assumption on $\bar {\rho }_{\mathfrak {m}}$, he also requires that the level is prime to $\ell$ and that $\ell$ is large compared to the weight giving rise to the local system. Since we make no assumption on the level at $\ell$, a standard argument using the Hochschild–Serre spectral sequence allows us to upgrade Theorem A to also apply to cohomology with twisted coefficients.
Let $p\not = \ell$ be a prime which splits completely in $F$ and such that $\bar {\rho }_{\mathfrak {m}}$ is unramified at every place of $F$ above $p$. If $v$ is such a place, we say that $\bar {\rho }_{\mathfrak {m}}$ is generic at $v$ if the eigenvalues of $\bar {\rho }_{\mathfrak {m}}(\mathrm {Frob}_v)$ have ratio different from $p^{\pm 1}$. If the projective image of $\bar {\rho }_{\mathfrak {m}}$ satisfies the condition in Remark 1.1.1$(1)$, then the Chebotarev density theorem implies, cf. Lemma 7.1.8, that there exists a prime $p$ as above such that $\bar {\rho }_{\mathfrak {m}}$ is generic at every $v\mid p$.Footnote 3 As in [Reference Caraiani and ScholzeCS17, Reference Caraiani and ScholzeCS19], Theorem A relies on the study of the cohomology of (perfectoid) Igusa varieties and on the geometry of the Hodge–Tate period map at the auxiliary prime $p$.
The key new idea in our situation is to establish a geometric Jacquet–Langlands transfer comparing the cohomology of Igusa varieties attached to different quaternionic Shimura varieties. This replaces the direct computation of the cohomology of Igusa varieties via the trace formula carried out in [Reference Caraiani and ScholzeCS17]. We also exploit the relation between Igusa varieties and fibres of the Hodge–Tate period map for compact quaternionic Shimura varieties. We explain this idea more in § 1.2.
Furthermore, Theorem A is obtained as a special case of the following more precise result, that probes the structure of the cohomology beyond the generic case. Given a prime $p$ which splits completely in $F$ and such that $\bar {\rho }_{\mathfrak {m}}$ is unramified at every place of $F$ above $p$, denote by $\delta _p(\mathfrak {m})\in [0,g]$ the number of places above $p$ where $\bar {\rho }_{\mathfrak {m}}$ is not generic.
Theorem B see Theorem 7.1.6
Let $\ell >2$ be a prime. Let $p\not = \ell$ be an odd prime which splits completely in $F$ and such that $K = K^pK_p$ with $K_p$ hyperspecial. Let $\mathfrak {m}\subset \mathbb {T}$ be a non-Eisenstein maximal ideal. Then
vanishes outside $i\in [g- \delta _p(\mathfrak {m}), g+\delta _p(\mathfrak {m})]$.
Theorem B is inspired by Arthur's conjectures [Reference ArthurArt96], describing the interplay between the Hecke action and the Lefschetz structure on the cohomology of Shimura varieties with ${\mathbb {C}}$-coefficients. Our result is consistent with the existence of such a structure on the cohomology with ${\mathbb {F}}_{\ell }$-coefficients as well.
In the case of Harris–Taylor unitary Shimura varieties, Boyer established the analogue of Theorem B in [Reference BoyerBoy19] (see also the discussion around [Reference KoshikawaKos20, Theorem 1.3]). Our argument is partly inspired by Boyer's, but it is different: we rely on the ingredients mentioned above, as well as on the affineness and smoothness of Newton strata. This allows us to apply Artin vanishing at a crucial step in the proof, followed by Poincaré duality.
Remark 1.1.2 (i) If $\delta _p(\mathfrak {m}) = 0$, we expect that $H^i_c(Sh_K(G), {\mathbb {F}}_{\ell })_{\mathfrak {m}} = 0$ for $i>g$ (and, dually, $H^i(Sh_K(G), {\mathbb {F}}_{\ell })_{\mathfrak {m}}=0$ for $i< g$) even without the non-Eisenstein assumption on $\mathfrak {m}$. This is the analogue of [Reference Caraiani and ScholzeCS19, Theorem 1.1] in our context. To establish this, one may need the semi-perversity result [Reference Caraiani and ScholzeCS19, Theorem 4.6.1] in our setting, which relies on a detailed understanding of toroidal compactifications of Igusa varieties.
(ii) Using the same method based on geometric Jacquet–Langlands, we also obtain analogues of Theorems A and B for compact quaternionic Shimura varieties, without the non-Eisenstein assumption: see Theorem 7.5.2.
As a quick application of Theorem A, we show that the $p$-adic local Langlands correspondence occurs in the completed homology of Hilbert modular varieties. More precisely, fix a prime $p>3$ which splits completely in $F$; in the following discussion, the prime $p$ will play the role of the prime denoted by $\ell$ above. Fix a large enough finite extension $L/{\mathbb {Q}}_p$ with ring of integers ${\mathcal {O}}$. Under suitable assumptions (e.g. hypothesis $(3)$ in Theorem C) we can attach to the restriction of $\bar {\rho }_{\mathfrak {m}}$ to places $v\mid p$ a universal local deformation ring $R_p^{\mathrm {loc}} :=\hat {\otimes }_{v\mid p, {\mathcal {O}}} R_v^{\mathrm {def}}$ and an $R_p^{\mathrm {loc}}$-module $P: =\hat {\otimes }_{v \mid p, {\mathcal {O}}}P_v$. The latter represents a large part of the $p$-adic local Langlands correspondence in this setting, cf. [Reference PaškūnasPaš13]. (See § 8 for more details on the notation.)
Theorem C Let $p>3$ be a prime which splits completely in $F$. Assume that the following assertions hold true.
(i) The projective image of the Galois representation $\bar {\rho }_\mathfrak {m}$ attached to $\mathfrak {m}$ contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_p)$ or is isomorphic to $A_5$.
(ii) If $\bar {\rho }_\mathfrak {m}$ is ramified at some place $v$ not lying above $p$, then $v$ is not a vexing prime.
(iii) For each place $v \mid p$, the restriction of $\bar {\rho }_\mathfrak {m}$ to $\Gamma _{F_v}$ is absolutely irreducible.
Then the completed homology $\tilde {H}_g(\bar {K}_1(N(\bar {\rho }_\mathfrak {m}))^p, {\mathcal {O}})_\mathfrak {m}$, as a module over $\mathbb {T}(\bar {K}_1(N(\bar {\rho }_\mathfrak {m}))^p)_\mathfrak {m}[\bar {G}({\mathbb {Q}}_p)]$, can be described as
for some $m \geq 1$.
Theorem C points towards an extension of Emerton's landmark local–global compatibility theorem for modular curves [Reference EmertonEme11] to the case of Hilbert modular varieties. Here, we apply the axiomatic approach via patching developed in [Reference Caraiani, Emerton, Gee, Geraghty, Paškūnas and Woo ShinCEG+18, Reference Gee and NewtonGN22] in order to obtain an unconditional ‘proof of concept’. We note that, for this application, it is crucial to know that completed homology is a projective object in an appropriate category of $\prod _{v\mid p}\operatorname {PGL}_2({\mathbb {Z}}_p)$-modules. This relies on knowing Theorem A with twisted coefficients coming from arbitrary Serre weights, something that is not available from the earlier results of [Reference DimitrovDim09]. In Remark 8.2.3, we also sketch how to obtain a version of compatibility with the $p$-adic local Langlands correspondence without any assumptions on the tame level.
Theorem A should have numerous other applications to the $p$-adic Langlands programme for $\operatorname {GL}_2$ over a totally real field $F$, including in the case when $p$ ramifies in $F$. Once cohomology is concentrated in one degree, one can combine the Taylor–Wiles–Kisin patching method with purely local techniques, as in [Reference Emerton, Gee and SavittEGS15, Reference Breuil, Hellmann and SchraenBHS19] (for example). Traditionally, these methods have been used for Shimura sets attached to definite unitary groups or for Shimura curves. The advantage of Hilbert modular varieties is that their (co)homology may be more suitable to studying low-weight forms, such as Hilbert modular forms of parallel weight $1$.
1.2 The method of proof
As we mentioned above, the proof of Theorems A and B uses the geometry of the Hodge–Tate period morphism at an auxiliary prime $p \neq \ell$ for quaternionic Shimura varieties, particularly the relation between fibres of this morphism and perfectoid Igusa varieties. The key new idea in the proof, inspired by the work of Tian and Xiao on the Goren–Oort stratification on quaternionic Shimura varieties [Reference Tian and XiaoTX16], is to establish instances of geometric Jacquet–Langlands functoriality for Igusa varieties. This idea, which was not present in either of [Reference Caraiani and ScholzeCS17, Reference Caraiani and ScholzeCS19], allows us to handle the cohomology of Igusa varieties. We exploit this (and further ingredients mentioned below) to transfer systems of Hecke eigenvalues in the cohomology of non-ordinary strata from Hilbert modular varieties to (perfectoid) compact quaternionic Shimura varieties. Using this we show that, in the setting of Theorem A, cohomology localised at $\mathfrak {m}$ must be supported on the ordinary locus; it is then relatively easy to prove that the cohomology is concentrated in one degree.
We illustrate a version of the key new idea mentioned above first using the toy model of the modular curve, the Shimura variety for $G:=\operatorname {GL}_2/{\mathbb {Q}}$. Let $K^p\subset G({\mathbb {A}}_f)$ be a sufficiently small compact open subgroup. By [Reference ScholzeSch15, § 3], we have the Hodge–Tate period morphism $\pi _{\mathrm {HT}}: \mathcal {S}h_{K^p}(G) \to \mathbb {P}^{1,\mathrm {ad}}$ and the Hodge–Tate period domain admits the Newton stratification
Here, $\mathbb {P}^1({\mathbb {Q}}_p)$ is the closed stratum corresponding to the ordinary locus and $\Omega ^2$, the Drinfeld upper half plane, is the open stratum corresponding to the supersingular locus. For every geometric point $x: \mathrm {Spa} (C, \mathcal {O}_C)\to \Omega ^2$, the fibre $\pi _{\mathrm {HT}}^{-1}(x)$ is a perfectoid version of a supersingular Igusa variety. In view of [Reference HoweHow22, Corollary 3.7.4] (which originates in an observation of Serre [Reference SerreSer96]), this can, in turn, be identified with the double coset $D^\times \backslash D^\times ({\mathbb {A}}_f)/K^p$, where $D/{\mathbb {Q}}$ is the quaternion algebra that is ramified precisely at $p$ and $\infty$. If $\mathfrak {m}\subset \mathbb {T}$ is a non-Eisenstein maximal ideal such that $(R\pi _{\mathrm {HT}*}{\mathbb {F}}_{\ell })_{\mathfrak {m}}$ is supported on $\Omega ^2$, then $\mathfrak {m}$ is also in the support of the module $H^0(D^\times \backslash D^\times ({\mathbb {A}}_f)/K^p, {\mathbb {Q}}_{\ell })$. This means that there exists a cuspidal automorphic representation of $D^\times$ whose associated Galois representation is a characteristic $0$ lift of $\bar {\rho }_{\mathfrak {m}}$.
However, if we choose $p$ such that $\bar {\rho }_{\mathfrak {m}}|_{\Gamma _{{\mathbb {Q}}_p}}$ is generic, then any characteristic $0$ lift corresponds, under the classical local Langlands correspondence, to a generic principal series representation of $\operatorname {GL}_2({\mathbb {Q}}_p)$. Such a representation cannot be the local component at $p$ of the global Jacquet–Langlands transfer of a cuspidal automorphic representation of $D^\times$. Therefore, if $\bar {\rho }_{\mathfrak {m}}$ is generic at $p$, then the complex of sheaves $(R\pi _{\mathrm {HT}*}{\mathbb {F}}_{\ell })_{\mathfrak {m}}$ is supported only on the ordinary locus $\mathbb {P}^1({\mathbb {Q}}_p)$.
Morally, the Hilbert case for a totally real field $F$ of degree $g$ behaves like a product of $g$ copies of the modular curve case. In this setting, Tian and Xiao establish geometric instances of the Jacquet–Langlands correspondence in [Reference Tian and XiaoTX16]. Inspired by their result in the case when $p$ splits completely in $F$, we express the geometric Jacquet–Langlands relation as a Hecke-equivariant isomorphism between Igusa varieties attached to different Shimura varieties, cf. Theorem 4.2.4.Footnote 4 In Theorem 6.3.3, we obtain a clean geometric description of the $\mu$-ordinary locus at infinite level on quaternionic Shimura varieties. This relies on (a perfectoid version of) the Mantovan product formula [Reference MantovanMan05], established in § 5, and on the induced structure of the corresponding Rapoport–Zink spaces, cf. [Reference HansenHan21, Reference Gaisin and ImaiGI16]. Theorems 4.2.4 and 6.3.3 allow us to transfer systems of mod $\ell$ Hecke eigenvalues between different Shimura varieties, which forms the basis for an inductive argument to prove Theorem B.
Some technical difficulties we encounter are that Hilbert modular varieties are Shimura varieties of abelian type and that they are non-compact. However, the non-compactness does not impose serious difficulties. The only Newton stratum that intersects the boundary of Hilbert modular varieties is the ordinary one. This, together with the geometric Jacquet–Langlands relation on the level of interior Igusa varieties, makes the analysis of interior Newton strata similar to that in [Reference Caraiani and ScholzeCS17]. Because we are localising at a non-Eisenstein maximal ideal, we avoid employing partial minimal and toroidal compactifications of Igusa varieties or semi-perversity; in particular, our argument is independent of [Reference Caraiani and ScholzeCS19], and only relies on the (easier) study of the geometry of the Hodge–Tate period map in the compact setting of [Reference Caraiani and ScholzeCS17].
Recently, Koshikawa [Reference KoshikawaKos21] gave a new strategy for proving the vanishing theorems of [Reference Caraiani and ScholzeCS17, Reference Caraiani and ScholzeCS19], removing most technical assumptions from these results. This strategy relies on [Reference Fargues and ScholzeFS21] together with the geometry of the Hodge–Tate period morphism. The idea is to show that only the cohomology of the ordinary locus contributes to the generic part of the cohomology of Shimura varieties, by proving a local vanishing theorem for the generic part of the cohomology of Rapoport–Zink spaces. After reducing to the ordinary locus, [Reference KoshikawaKos21] uses the semi-perversity result mentioned above to control the range of degrees of cohomology. Koshikawa's arguments could be applied in the Hilbert setting as well, though this would require some version of our results in § 5 and semi-perversity. One advantage of our method is that it gives information about the complexes of sheaves $(R\pi _{\mathrm {HT}*}{\mathbb {F}}_{\ell })_{\mathfrak {m}}$ rather that just the cohomology groups $H^*(Sh_K(G), {\mathbb {F}}_{\ell })_{\mathfrak {m}}$.
1.3 Notation
We use the following notation throughout the paper, unless otherwise stated.
The cardinality of a set $T$ is denoted by $|T|$.
The symbol $\otimes$ stands for $\otimes _{{\mathbb {Z}}}$. If $A$ is an abelian group, we let $\hat {A} = A\otimes \hat {{\mathbb {Z}}}$ and $\hat {A}^{(p)} = A\otimes \hat {{\mathbb {Z}}}^{(p)}$. We also set ${\mathbb {A}}_f = \hat {{\mathbb {Q}}}$, the finite adeles of ${\mathbb {Q}}$, and ${\mathbb {A}}_f^{(p)} = \hat {{\mathbb {Q}}}^{(p)}$, the finite adeles of ${\mathbb {Q}}$ away from $p$.
If $L$ is a perfect field, we denote by $\bar {L}$ an algebraic closure of $L$, and by $\Gamma _L$ the absolute Galois group $\operatorname {Gal}(\bar {L}/L)$. Assume now that $L$ is a number field. If $v$ is a finite place of $L$, we denote by $L_v$ the completion of $L$ at $v$, and by ${\mathcal {O}}_v$ the ring of integers of $L_v$. We denote by $\varpi _v$ a uniformiser of ${\mathcal {O}}_v$, and by $N(v)$ the cardinality of the residue field ${\mathcal {O}}_v/(\varpi _v)$. We denote by $\mathrm {Frob}_v$ the geometric Frobenius at $v$. We let ${\mathbb {A}}_{L,f} = \hat {L}$, the ring of finite adeles of $L$.
If $A\to B$ is a ring morphism and $S\to \operatorname {Spec} A$ is a scheme, we denote by $S_B$ the base change $S\times _{\operatorname {Spec} A} \operatorname {Spec} B$. We use a similar notation for adic spaces. If $S$, $T$ are two schemes over ${\mathbb {Q}}$, we denote by $S\times T$ the fibre product $S\times _{\operatorname {Spec} {\mathbb {Q}}} T$.
If $L$ is a field and $S$ is a variety or adic space over $L$, the symbols $H^i(S, {\mathbb {F}}_{\ell })$, $H^i(S, {\mathbb {Z}}_{\ell })$ and $H^i(S, {\mathbb {Q}}_{\ell })$ denote the étale (respectively, $\ell$-adic étale) cohomology of $S_{\bar {L}}$.
2. Hilbert modular varieties and Galois representations
In this section, we establish some preliminary results about Hilbert modular varieties. In particular, we construct Galois representations attached to systems of Hecke eigenvalues occurring in their cohomology with ${\mathbb {F}}_{\ell }$-coefficients, using [Reference ScholzeSch15].
2.1 Shimura varieties and locally symmetric spaces for $\mathrm {Res}_{F/{\mathbb {Q}}}\mathrm {GL}_2$
Fix a totally real number field $F$ of degree $[F: {\mathbb {Q}}]=: g$, and let ${\mathcal {O}}_F$ be the ring of integers of $F$. Totally positive elements in $F$ (respectively, ${\mathcal {O}}_F$) will be denoted by $F^+$ (respectively, ${\mathcal {O}}_F^+$). Let $\Sigma _{\infty }: =\{\tau _1, \ldots, \tau _g\}$ be the set of real embeddings of $F$; let $G:=\mathrm {Res}_{F/{\mathbb {Q}}}\mathrm {GL}_2$ with centre $Z \simeq \mathrm {Res}_{F/{\mathbb {Q}}}\mathbb {G}_m$.
2.1.1
Let $\mathbb {S}:=\mathrm {Res}_{{\mathbb {C}}/{\mathbb {R}}}\mathbb {G}_m$ be the Deligne torus, and let $h : \mathbb {S} \rightarrow G_{{\mathbb {R}}}\simeq \prod _{i=1}^g \operatorname {GL}_{2, {\mathbb {R}}}$ be the morphism which on ${\mathbb {R}}$-points is given by
Let $K^\circ _\infty : =\prod _{i=1}^g\mathrm {SO}_2({\mathbb {R}})\subset G({\mathbb {R}})$ (a maximal compact connected subgroup). The $G({\mathbb {R}})$-conjugacy class of $h$, denoted by $X$, is identified with $G({\mathbb {R}})/Z({\mathbb {R}})K^\circ _\infty \simeq ({\mathbb {C}}\smallsetminus {\mathbb {R}})^g$, and the couple $(G, X)$ is a Shimura datum with reflex field ${\mathbb {Q}}$. For every compact open subgroup $K \subset G({\mathbb {A}}_f)$ the Shimura variety $Sh_K(G)$ is a quasi-projective variety with a canonical model over the reflex field ${\mathbb {Q}}$, with complex analytic uniformisation
The Shimura varieties $Sh_K(G)$ are called Hilbert modular varieties. If $K\subset G({\mathbb {A}}_f)$ is neat (which we will always assume in what follows), then $Sh_K(G)$ is smooth; moreover, if $K'\subset K$ is a normal compact open subgroup then the map $Sh_{K'}(G)\rightarrow Sh_{K}(G)$ is a finite étale Galois cover.
We have a map
induced by the map sending $(x_\infty, x_f) \in G({\mathbb {R}}) \times G({\mathbb {A}}_f)$ to $(\mathrm {sgn} \det x_\infty, \det x_f)$. An element in $F^\times$ acts on $\{\pm 1\}^g$ by multiplying by the sign of the image via each real embedding. Fibres of the map in (2.1.1.1) are connected components of the source.
2.1.2 Hecke action
We have the Hecke algebra $\mathbb {T}_K(G) :={\mathbb {Z}}[K\backslash G({\mathbb {A}}_f)/K]$ of compactly supported, $K$-bi-invariant functions on $G({\mathbb {A}}_f)$, with multiplication given by convolution. Every element of $\mathbb {T}_K(G)$ gives rise to a correspondence on $Sh_K(G)$ as follows: given $g \in G({\mathbb {A}}_f)$, let $K_g:=K \cap g K g^{-1}$; we have a correspondence $[KgK]$ on $Sh_K(G)$ given by the following diagram.
Here the vertical maps are the canonical projections and the upper horizontal map on complex points is induced by right multiplication by $g$ on $G({\mathbb {A}}_f)$. Therefore, we obtain an action of $\mathbb {T}_K(G)$ on the cohomology groups $H^i(Sh_K(G), {\mathbb {F}}_\ell )$ as well as on the cohomology groups with compact support $H^i_{\rm c}(Sh_K(G), {\mathbb {F}}_\ell )$, where $\ell$ is a prime number. In the rest of the paper, we will rather work with a smaller Hecke algebra, defined as follows: fix a finite set $S$ of places of $F$ containing all the infinite places, all the places $v\mid \ell$, and all the finite places $v$ such that $K_v$ is not conjugate to $\operatorname {GL}_2({\mathcal {O}}_v)$, where ${\mathcal {O}}_v$ is the ring of integers in the completion $F_v$ of $F$ at $v$. Let
denote the abstract spherical Hecke algebra away from $S$. For every $v\not \in S$, choose a uniformiser $\varpi _v$ of ${\mathcal {O}}_v$. We denote by $T_v$ the double coset $\operatorname {GL}_2({\mathcal {O}}_v)(\begin{smallmatrix} \varpi _v & 0\\ 0 & 1 \end{smallmatrix})\operatorname {GL}_2({\mathcal {O}}_v)$ and by $S_v$ the double coset $\operatorname {GL}_2({\mathcal {O}}_v)(\begin{smallmatrix} \varpi _v & 0\\ 0 & \varpi _v \end{smallmatrix})\operatorname {GL}_2({\mathcal {O}}_v)$, seen as elements of $\mathbb {T}$. The algebra $\mathbb {T}$ is commutative and is generated by the operators $T_v$, $S_v^{\pm 1}$ for $v \not \in S$. The inversion map on $G$ induces a map $\iota : \mathbb {T}\rightarrow \mathbb {T}$; for a maximal ideal $\mathfrak {m} \subset \mathbb {T}$ we denote by $\mathfrak {m}^\vee$ its image via $\iota$.
2.1.3 Locally symmetric spaces
We have the locally symmetric space $X_K(G)$ attached to $G$ and $K$, defined as follows:
Letting $Z_K:=Z({\mathbb {Q}})\cap K$, the quotient $T_K:=Z({\mathbb {R}})/\{\pm 1\}^g{\mathbb {R}}_{>0}Z_K$ is a torus of dimension $g-1$ by Dirichlet's unit theorem, and the projection $X_K(G) \rightarrow Sh_K(G)$ is a $T_K$-bundle (see [Reference GrafGra16, Lemma 3.1.2]). Let us define $K_\infty :=\prod _{i=1}^g\mathrm {O}_2({\mathbb {R}})$, and let us consider the space
In other words, we are quotienting by a maximal compact subgroup at infinity instead of its connected component of the identity. This is the space used in [Reference ScholzeSch15] (see the introduction there). The matrix $(\begin{smallmatrix}-1 & 0\\ 0 & 1\end{smallmatrix})$ normalises $\mathrm {SO}_2({\mathbb {R}})$; hence, we get a right action of $C:=({\mathbb {Z}}/2{\mathbb {Z}})^g$ on $X_K(G)$, and we have $\bar {X}_K(G)=X_K(G)/C$. The recipe given above endows the (Betti) cohomology of $X_K(G)$ and $\bar {X}_K(G)$ with an action of $\mathbb {T}$, which commutes with the action of $C$. Furthermore, if we make $C$ act on $F^\times \backslash \{\pm 1\}^g \times {\mathbb {A}}_{F, f}^\times / \det (K)$ by switching signs at archimedean places, then the map in (2.1.1.1) is $C$-equivariant.
Let $\hat {C}$ be the set of characters of $C$ with values in ${\mathbb {F}}_\ell ^\times$. The following lemma relates the cohomology of the spaces $Sh_K(G), X_K(G)$ and $\bar {X}_K(G)$.
Lemma 2.1.4 Let $\ell$ be an odd prime.
(i) Assume that $\det (K)=K \cap Z({\mathbb {A}}_f)$. Then for every $i \geq 0$ the pullback map $H^i(Sh_K(G), {\mathbb {F}}_\ell ) \rightarrow H^i(X_K(G), {\mathbb {F}}_\ell )$ is injective.
(ii) Assume that $\det (K) \cap F^\times$ only consists of totally positive elements. Then there is a Hecke-equivariant decomposition
\[ H^*(X_K(G), {\mathbb{F}}_\ell)=\bigoplus_{\chi \in \hat{C}}H^*(X_K(G), {\mathbb{F}}_\ell)^\chi \]and pullback induces an isomorphism $H^*(\bar {X}_K(G), {\mathbb {F}}_\ell )\simeq H^*(X_K(G), {\mathbb {F}}_\ell )^{\mathrm {Id}}$.
Proof. (i) Under the assumption that $\det (K)=K \cap Z({\mathbb {A}}_f)$, [Reference GrafGra16, Proposition 3.3.9] constructs cohomology classes in $H^*(X_K(G), {\mathbb {F}}_\ell )$ whose restrictions to each fibre of the map $X_K(G)\rightarrow Sh_K(G)$ give a basis of its cohomology; the statement hence follows from the Leray–Hirsch theorem.
(ii) Since $\det (K) \cap F^\times$ consists of totally positive elements by assumption, an explicit computation shows that $C$ acts freely on $F^\times \backslash \{\pm 1\}^g \times {\mathbb {A}}_{F, f}^\times / \det (K)$. In other words, the group $C$ acts on $X_K(G)$ freely permuting connected components. This implies that $H^*(\bar {X}_K(G), {\mathbb {F}}_\ell )\simeq H^*(X_K(G), {\mathbb {F}}_\ell )^{\mathrm {Id}}$. The Hecke-equivariance of the direct sum decomposition in the statement follows from the fact that the action of $C$ commutes with the Hecke action.
2.2 Construction of Galois representations
The aim of this section is to prove the following result.
Theorem 2.2.1 Let $\ell$ be an odd prime and $K\subset G({\mathbb {A}}_f)$ a neat compact open subgroup. Let $\mathfrak {m} \subset \mathbb {T}$ be a maximal ideal in the support of $H^i(Sh_K(G), {\mathbb {F}}_{\ell })$ or $H^i_{\rm c}(Sh_K(G), {\mathbb {F}}_{\ell })$ for some $i \geq 0$. There is a unique continuous, semisimple, totally odd Galois representation
such that, for all but finitely many places $v$ of $F$, $\bar {\rho }_\mathfrak {m}$ is unramified at $v$ and the characteristic polynomial of $\bar {\rho }_{\mathfrak {m}}(\mathrm {Frob}_v)$ is equal to $X^2-T_vX+S_vN(v) \pmod {\mathfrak {m}}$.
Remark 2.2.2 One could prove the above result by adapting the arguments in Chapter IV of [Reference ScholzeSch15]. The main technical point one needs to deal with is the construction of ad hoc compactifications of Hilbert modular varieties.Footnote 5 For the sake of brevity, we will instead explain below how to deduce the theorem from (a special case of) the main result of [Reference ScholzeSch15]; however, at the time of writing, the totally real case of the latter is conditional on Arthur's work [Reference ArthurArt13].
Proof. Uniqueness of $\bar {\rho }_\mathfrak {m}$ follows from the Chebotarev density theorem and the Brauer–Nesbitt theorem; to prove existence of $\bar {\rho }_{\mathfrak {m}}$ it suffices to consider the cohomology groups $H^*(Sh_K(G), {\mathbb {F}}_{\ell })$ (by Poincaré duality and the discussion in [Reference Caraiani and ScholzeCS19, p. 35]). Furthermore, if $K' \subset K$ is a normal compact open subgroup, then there is a Hecke-equivariant Hochschild–Serre spectral sequence relating cohomology of $Sh_{K'}(G)$ and $Sh_K(G)$. Therefore, at the cost of possibly enlarging the set $S$ in § 2.1.2, we may replace $K$ by a normal compact open subgroup. In particular, we may take $K=K(N)$ for $N$ large enough, where $K(N):=\{M \in GL_2(\hat {\mathcal {O}}_F)\mid M \equiv (\begin{smallmatrix} 1 & 0\\ 0 & 1 \end{smallmatrix}) \pmod N\}$. This ensures that the assumption in the first point of Lemma 2.1.4 is satisfied. Furthermore, Chevalley's theorem on units guarantees that we may choose $N$ in such a way that the hypothesis in the second point of Lemma 2.1.4 is satisfied as well. We fix such an integer $N$ from now on. By assumption there is $i \geq 0$ such that $H^i(Sh_K(G), {\mathbb {F}}_\ell )_\mathfrak {m}\neq 0$. By Lemma 2.1.4 we deduce that $H^i(X_K(G), {\mathbb {F}}_\ell )_\mathfrak {m} \neq 0$, hence $H^i(X_K(G), {\mathbb {F}}_\ell )_\mathfrak {m}^\chi \neq 0$ for some $\chi \in \hat {C}$. If $\chi$ is the trivial character, then by Lemma 2.1.4 we have $H^i(\bar {X}_K(G), {\mathbb {F}}_\ell )_\mathfrak {m}\neq 0$, and by [Reference ScholzeSch15, Theorem 1.3] and [Reference Caraiani and Le HungCL16, Theorem 1.2] we can attach to $\mathfrak {m}$ a Galois representation as in the statement of the theorem.
Now let us suppose that $\chi$ is not the trivial character. The map $\{\pm 1\}^g \rightarrow F^\times \backslash \{\pm 1\}^g \times {\mathbb {A}}_{F, f}^\times / \det (K)$ sending $\varepsilon$ to the equivalence class of $(\varepsilon, 1)$ is injective. We may extend $\chi : \{\pm 1\}^g\rightarrow {\mathbb {F}}_\ell ^\times$ to a character $\psi : F^\times \backslash \{\pm 1\}^g \times {\mathbb {A}}_{F, f}^\times / \det (K)\rightarrow k^\times$ for a large enough finite extension $k$ of ${\mathbb {F}}_\ell$. The function $\psi$ gives rise to a cohomology class $c_\psi \in H^0(X_K(G), k)$. Let $f_\psi : \mathbb {T} \rightarrow \mathbb {T}$ the map sending the operator $T_g$ attached to the double coset of $g \in G({\mathbb {A}}_f)$ to $\psi (\det (g)^{-1})T_g$. Cup product with $c_\psi$ induces a map $H^i(X_K(G), k)\rightarrow H^i(X_K(G), k)$ which is Hecke-equivariant if we endow the source (respectively, target) with the usual Hecke action (respectively, the composite of the usual Hecke action and $f_\psi$). This is proved in great generality in [Reference Allen, Calegari, Caraiani, Gee, Helm, Le Hung, Newton, Scholze, Taylor and ThorneACC+23, Proposition 2.2.22], and it can be checked in our situation by a direct computation.
Furthermore, the above map sends $H^i(X_K(G), k)^\chi$ to $H^i(X_K(G), k)^{\mathrm {Id}}$. Indeed, for $\varepsilon \in C$ we have $\varepsilon ^*(c_\psi )=\chi (\varepsilon )c_\psi$; hence, for every $c \in H^i(X_K(G), k)^\chi$:
The outcome of our discussion is that, letting $\mathfrak {m}(\psi ):=f_\psi (\mathfrak {m})$, we have the equivalence
We deduce that $H^i(\bar {X}_K(G), k)_{\mathfrak {m}(\psi )}\neq 0$, hence we have a Galois representation $\bar {\rho }_{\mathfrak {m}(\psi )}$ attached to $\mathfrak {m}(\psi )$ by [Reference ScholzeSch15, Theorem 1.3]. We can finally take $\bar {\rho }_\mathfrak {m}$ to be the twist of $\bar {\rho }_{\mathfrak {m}(\psi )}$ by the character of $\Gamma _F$ corresponding to $\psi$ via global class field theory.
2.3 Cohomology of the boundary
Recall that a maximal ideal $\mathfrak {m}\subset \mathbb {T}$ in the support of $H^*(Sh_K(G), {\mathbb {F}}_\ell )$ is said to be non-Eisenstein if the associated Galois representation $\bar {\rho }_\mathfrak {m}$ is absolutely irreducible.
Lemma 2.3.1 Let $\ell >2$ be a prime and assume that $\mathfrak {m}$ is non-Eisenstein. Then:
(i) for every integer $i$, the natural map from compactly supported cohomology to cohomology induces an isomorphism $H^i_c(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}\simeq H^i(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}$;
(ii) take $\delta \geq 0$ and assume that $H^i_c(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}=H^i_c(Sh_K(G), {\mathbb {F}}_{\ell })_{\mathfrak {m}^\vee }=0$ for each $i < g-\delta$; then $H^i(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ if $i$ is outside the interval $[g-\delta, g+\delta ]$.
Proof. Consider the Borel–Serre compactification $Sh_K(G)^{BS}$ of $Sh_K(G)$, constructed in [Reference HarderHar87], with boundary $\partial$. Recall that the cohomology of $Sh_K(G)^{BS}$ agrees with that of $Sh_K(G)$, as the two spaces are homotopy equivalent, and the compactly supported cohomology of $Sh_K(G)$ coincides with the cohomology of $Sh_K(G)^{BS}$ relative to the boundary. Hence, we have a $\mathbb {T}$-equivariant long exact sequence
We claim that if $\mathfrak {m}$ is non-Eisenstein then cohomology of the boundary vanishes after localising at $\mathfrak {m}$; this implies the first point. The second follows using Poincaré duality (which interchanges $\mathfrak {m}$ and $\mathfrak {m}^\vee$, as in [Reference Caraiani and ScholzeCS19, p. 35]). It remains to justify our claim. By [Reference HarderHar87, p. 46] we have $H^*(\partial, {\mathbb {F}}_\ell )\simeq H^*(P({\mathbb {Q}})\backslash ({\mathbb {C}} \smallsetminus {\mathbb {R}})^g \times G({\mathbb {A}}_f)/K, {\mathbb {F}}_\ell )$, where $P \subset G$ is the standard upper parabolic. To prove our claim we may replace $K$ by a normal compact open subgroup, so that the condition $\det (K)=K \cap Z({\mathbb {A}}_f)$ is satisfied. We will assume that this is the case in the rest of the proof. The space $P({\mathbb {Q}})\backslash ({\mathbb {C}} \smallsetminus {\mathbb {R}})^g \times G({\mathbb {A}}_f)/K$ is a disjoint union of quotients $P({\mathbb {Q}})\cap g_iKg_i^{-1}\backslash ({\mathbb {C}}\smallsetminus {\mathbb {R}})^g$, where $g_i$ runs over a set of representatives of $P({\mathbb {Q}})\backslash G({\mathbb {A}}_f)/K$.
On the other hand, we have the locally symmetric space $X_K(G)$. The boundary of its Borel–Serre compactification is homotopy equivalent to the space $P({\mathbb {Q}}) \backslash G({\mathbb {R}})\times G({\mathbb {A}}_f)/({\mathbb {R}}_{>0}K^\circ _\infty ) K$ (see [Reference GrafGra16, p. 94]). The latter is a disjoint union of quotients $P({\mathbb {Q}})\cap g_iKg_i^{-1}\backslash G({\mathbb {R}})/({\mathbb {R}}_{>0}K^\circ _\infty )$ with $g_i$ as above. The action of $Z({\mathbb {R}})$ on $G({\mathbb {R}})/({\mathbb {R}}_{>0}K^\circ _\infty )$ induces an action on $P({\mathbb {Q}}) \backslash G({\mathbb {R}})\times G({\mathbb {A}}_f)/({\mathbb {R}}_{>0}K^\circ _\infty ) K$. This action preserves the fibres of the projection map
and factors through an action of the torus $T_K=Z({\mathbb {R}})/\{\pm 1\}^g{\mathbb {R}}_{>0}Z_K$. The argument in the proof of [Reference GrafGra16, Lemma 3.1.2] shows that each projection map $P({\mathbb {Q}})\cap g_iKg_i^{-1}\backslash G({\mathbb {R}})/({\mathbb {R}}_{>0}K^\circ _\infty ) \rightarrow P({\mathbb {Q}})\cap g_iKg_i^{-1}\backslash ({\mathbb {C}}\smallsetminus {\mathbb {R}})^g$ is a $T_K$-bundle. Hence, the same is true for the map in (2.3.1.1). Furthermore, we have the following commutative diagram.
As we already mentioned, by [Reference GrafGra16, Lemma 3.1.2] the right vertical map is a $T_K$-bundle, and [Reference GrafGra16, Proposition 3.3.9] constructs cohomology classes in $H^*(X_K(G), {\mathbb {F}}_\ell )$ whose restrictions to each fibre of the right vertical map give a basis of its cohomology. Pulling back via the upper horizontal map we obtain classes in $H^*(P({\mathbb {Q}}) \backslash G({\mathbb {R}})\times G({\mathbb {A}}_f)/({\mathbb {R}}_{>0}K^\circ _\infty ) K, {\mathbb {F}}_\ell )$ enjoying the same property. In particular, by Leray–Hirsch the pullback map in cohomology induced by the left vertical map is injective. Now assume that $H^*(\partial, {\mathbb {F}}_\ell )_\mathfrak {m}=H^*(P({\mathbb {Q}}) \backslash ({\mathbb {C}} \smallsetminus {\mathbb {R}})^g\times G({\mathbb {A}}_f)/K, {\mathbb {F}}_\ell )_\mathfrak {m}\neq 0$. We deduce that the cohomology $H^*(P({\mathbb {Q}}) \backslash G({\mathbb {R}})\times G({\mathbb {A}}_f)/({\mathbb {R}}_{>0}K^\circ _\infty ) K, {\mathbb {F}}_\ell )_\mathfrak {m}$ of the boundary of $X_K(G)$ is non-zero. Finally the argument in [Reference Newton and ThorneNT16, § 4] shows that $\mathfrak {m}$ must be Eisenstein.
3. Quaternionic and unitary Shimura varieties
In this section, we introduce quaternionic Shimura varieties as well as certain closely related unitary Shimura varieties that admit nice integral models.
3.1 Quaternionic Shimura data and the associated unitary Shimura data
3.1.1 Quaternionic Shimura data
As in the previous section we use the notation $G:=\mathrm {Res}_{F/{\mathbb {Q}}}\mathrm {GL}_2$; we also let $T_F:=\mathrm {Res}_{F/{\mathbb {Q}}}\mathbb {G}_m$. Let $K\subset G({\mathbb {A}}_f)$ be a neat compact open subgroup. Fix a prime $p>2$ which is totally split in $F$ and such that $K=K^{p}K_p$ with $K_p=\operatorname {GL}_2({\mathcal {O}}_F\otimes {\mathbb {Z}}_p)$.
Recall that $\Sigma _\infty$ denotes the set of real places of $F$. We will denote by $\Sigma _p$ the set of embeddings of $F$ into $\bar {{\mathbb {Q}}}_p$, which we identify with the set of prime ideals $\mathfrak {p} \subset {\mathcal {O}}_F$ lying above $p$. We fix an isomorphism $\iota _p : \bar {{\mathbb {Q}}}_p \buildrel \sim \over \to {\mathbb {C}}$, inducing a bijection $\iota _{p, \infty }: \Sigma _p \buildrel \sim \over \to \Sigma _\infty$. For every subset $T \subset \Sigma _p$ we set $T_\infty :=\iota _{p, \infty }(T)$ and we denote by $B_T$ the quaternion algebra over $F$ ramified precisely at $T \coprod T_\infty$. We let $G_T:=\mathrm {Res}_{F/{\mathbb {Q}}}B_T^\times$, and we fix an isomorphism $G_T({\mathbb {A}}_f^{(p)})\simeq G({\mathbb {A}}_f^{(p)})$. The group $G_{T, {\mathbb {R}}}$ is isomorphic to $\prod _{\tau \in T_\infty } \mathbb {H}^\times \times \prod _{\tau \in \Sigma _\infty \smallsetminus T_\infty } \operatorname {GL}_{2, {\mathbb {R}}}$ where $\mathbb {H}$ is the algebra of Hamilton quaternions. Let $X_T$ be the $G_T({\mathbb {R}})$-conjugacy class of the morphism $h_T: \mathbb {S} \rightarrow G_{T, {\mathbb {R}}}$ sending an ${\mathbb {R}}$-point $z=a+ib \in \mathbb {S}({\mathbb {R}})$ to $(z^\tau )_{\tau \in \Sigma _\infty }$, where $z^\tau =1$ for $\tau \in T_\infty$ and $z^\tau =(\begin{smallmatrix} a & b\\ -b & a \end{smallmatrix})$ if $\tau \in \Sigma _\infty \smallsetminus T_\infty$. The couple $(G_T, X_T)$ is a weak Shimura datum (in the sense of [Reference Tian and XiaoTX16, § 2.2]) whose reflex field $F_T$ can be described as follows: the group $\mathrm {Aut}({\mathbb {C}}/{\mathbb {Q}})$ acts on $\Sigma _\infty$ by post-composition. Let $\Gamma _T \subset \mathrm {Aut}({\mathbb {C}}/{\mathbb {Q}})$ be the subgroup preserving $T_\infty$; then $F_T={\mathbb {C}}^{\Gamma _T}\subset {\mathbb {C}}$.
Let $K_T=K_{T, p}K^{p} \subset G_T({\mathbb {A}}_f)$ be the compact open subgroup such that $K^p\subset G_T({\mathbb {A}}_f^{(p)})\simeq G({\mathbb {A}}_f^{(p)})$ is the subgroup chosen above and $K_{T, p}=\prod _{\mathfrak {p} \mid p}K_{T, \mathfrak {p}}$ is of the following type: if $\mathfrak {p} \in \Sigma _p \smallsetminus T$, then we fix an isomorphism $\rho _\mathfrak {p}: B_T(F_\mathfrak {p})^\times \rightarrow \operatorname {GL}_2(F_\mathfrak {p})$ and we take $K_{T, \mathfrak {p}}:=\rho _\mathfrak {p}^{-1}(\operatorname {GL}_2(\mathcal {O}_\mathfrak {p}))$. If $\mathfrak {p} \in T$, then we take $K_{T, \mathfrak {p}}$ to be the group of units in the unique maximal order in the division quaternion algebra $B_T \otimes _F F_\mathfrak {p}$.
3.1.2 The auxiliary $CM$ extension
Choose a $CM$ extension $E/F$ such that every place $\mathfrak {p} \in \Sigma _p$ is inert in $E$; in particular, $B_T \otimes _F E$ is isomorphic to the matrix algebra $M_2(E)$. Let $c \in \mathrm {Gal}(E/F)$ be the non trivial element and let $\Sigma _{E, \infty }$ be the set of complex embeddings of $E$: it comes with a restriction map $\Sigma _{E, \infty }\rightarrow \Sigma _\infty$ whose fibres are the orbits for the action of $\mathrm {Gal}(E/F)$ sending an embedding $\tilde {\tau } \in \Sigma _{E, \infty }$ to $\tilde {\tau }^c:=\tilde {\tau }\circ c$. Choose a set $\tilde {T} \subset \Sigma _{E, \infty }$ containing exactly one lift of each $\tau \in T_\infty$. For every $\tilde {\tau } \in \Sigma _{E, \infty }$, define an integer $s_{\tilde {\tau }} \in \{0, 1, 2\}$ as follows:
• if $\tilde {\tau }_{|F} \not \in T_\infty$ then $s_{\tilde {\tau }}=1$;
• if $\tilde {\tau } \in \tilde {T}$ then $s_{\tilde {\tau }}=0$;
• if $\tilde {\tau }^c \in \tilde {T}$ then $s_{\tilde {\tau }}=2$.
For each $\tau \in T_\infty$ (respectively, $\tau \in \Sigma _\infty \smallsetminus T_\infty$) we choose the isomorphism $E\otimes _{F, \tau }{\mathbb {R}}\simeq {\mathbb {C}}$ induced by the embedding $\tilde {\tau } \in \Sigma _{E, \infty }\smallsetminus \tilde {T}$ lifting $\tau$ (respectively, an arbitrary lift of $\tau$). Let $T_E:=\mathrm {Res}_{E/{\mathbb {Q}}}\mathbb {G}_m$; via the previous choices we obtain an isomorphism $T_{E}({\mathbb {R}})= \prod _{\tau \in \Sigma _\infty }(E\otimes _{F, \tau }{\mathbb {R}})^\times \simeq \prod _{\tau \in \Sigma _\infty }{\mathbb {C}}^\times$. Let $h_{T, E}: \mathbb {S} \rightarrow T_{E, {\mathbb {R}}}$ be the morphism which on ${\mathbb {R}}$-points sends $z=a+ib \in \mathbb {S}({\mathbb {R}})$ to $(z^\tau )_{\tau \in \Sigma _\infty }$, where $z^\tau =z$ (respectively, $z^\tau =1$) if $\tau \in T_\infty$ (respectively, $\tau \in \Sigma _\infty \smallsetminus T_\infty$). The reflex field $E_T\supset F_T$ of the $T_E({\mathbb {R}})-$conjugacy class of $h_{T, E}$ is the subfield of ${\mathbb {C}}$ fixed by the stabiliser in $\mathrm {Aut}({\mathbb {C}}/{\mathbb {Q}})$ of $\tilde {T}$.
3.1.3 Unitary Shimura data
We denote by $H_T$ the algebraic group fitting in the exact sequence
where the map $T_F \rightarrow G_T \times T_E$ is given by $a \mapsto (a, a^{-1})$. Note that, because of Hilbert's theorem 90, the map $G_T \times T_E \rightarrow H_T$ induces surjections on ${\mathbb {Q}}$-points and ${\mathbb {A}}_f$-points. The $(G_T \times T_E)({\mathbb {R}})-$conjugacy class of the map $h_T\times h_{T, E}: \mathbb {S}\rightarrow (G_T \times T_E)_{\mathbb {R}}$ and the $H_T({\mathbb {R}})$-conjugacy class of the induced map $h_{H_T}: \mathbb {S}\rightarrow H_{T, {\mathbb {R}}}$ can both be identified with $X_T \simeq \prod _{\tau \in \Sigma _\infty \smallsetminus T_\infty }({\mathbb {C}} \smallsetminus {\mathbb {R}})$, and they give rise to weak Shimura data $(G_T \times T_E, X_T)$ and $(H_T, X_T)$ with reflex field $E_T$. We let $X_{T}^+:=\prod _{\tau \in \Sigma _\infty \smallsetminus T_\infty }({\mathbb {C}} \smallsetminus {\mathbb {R}})^+$, where $({\mathbb {C}} \smallsetminus {\mathbb {R}})^+ \subset ({\mathbb {C}} \smallsetminus {\mathbb {R}})$ is the upper half-plane.
Let us denote by $D_T$ the tensor product $B_T\otimes _F E$ and by $\overline {(\cdot )}: D_T \rightarrow D_T$ the tensor product of the main involution on $B_T$ and complex conjugation on $E$. For every ${\mathbb {Q}}-$algebra $R$ we have a canonical isomorphism
hence we get a map $G_T(R) \times T_E(R) \rightarrow (D_T \otimes _{\mathbb {Q}} R)^\times$. This yields an identification
The latter description allows to see $H_T$ as a unitary group as follows: given an element $\sigma \in D_T$ such that $\bar {\sigma }=-\sigma$ the map sending $g \in D_T$ to $g^*=\sigma ^{-1}\bar {g}\sigma$ is an involution of $D_T$. Let us denote by $V_T$ the ${\mathbb {Q}}$-vector space underlying $D_T$, together with its natural structure of left $D_T$-module, so that $\mathrm {End}_{D_T}(V_T)=D_T^{op}$. Consider the skew-Hermitian pairing
for every $g \in D_T$ and $v, w \in V_T$ we have
hence, for every ${\mathbb {Q}}$-algebra $R$,
3.2 Relation between quaternionic and unitary Shimura varieties
3.2.1
Fix a subset $T\subset \Sigma _p$; the reduced norm on $B_T$ gives rise to a map $\mathrm {Nm}: G_T \rightarrow T_F$. Let $T_{H_T}:=(T_F \times T_E)/T_F$, where the embedding of $T_F$ in $T_F \times T_E$ is given by $a \mapsto (a^2, a^{-1})$. Letting $N_{H_T}: H_T \rightarrow T_{H_T}$ be the map induced by $\mathrm {Nm} \times \mathrm {Id}: G_T \times T_E \rightarrow T_F \times T_E$, we obtain a commutative diagram
where the top arrow is compatible with the Deligne homomorphisms. Recall that we have fixed a compact open subgroup $K_T \subset G_T({\mathbb {A}}_f)$. Take a compact open subgroup $K_E=K_{E, p} K_E^{p} \subset T_E({\mathbb {A}}_f)$ and a compact open subgroup $U_T \subset H_T({\mathbb {A}}_f)$ containing the image of $K_T \times K_E$. Let
where $T_{H_T}({\mathbb {Q}})^+:=(F^{\times, +}\times E^\times )/F^\times$. We have maps $C_{K_T}\rightarrow C_{K_T}\times C_{K_E} \rightarrow C_{U_T}$, where the first map sends $C_{K_T}$ to (the equivalence class of) 1 on the second component. Letting $G_T({\mathbb {Q}})^+\subset G_T({\mathbb {Q}})$ be the subgroup of elements with totally positive norm, and $H_T({\mathbb {Q}})^+:=(G_T({\mathbb {Q}})^+\times T_E({\mathbb {Q}}))/T_F({\mathbb {Q}})$, we obtain the following commutative diagram.
If $T \neq \Sigma _p$ (so that the spaces in the top row are positive dimensional), the fibres of the vertical maps are connected components of the complex analytic spaces in the first row. The upper left (respectively, upper right) space is identified with the complex points of $Sh_{K_T}(G_T)$ (respectively, $Sh_{U_T}(H_T)$). If $T=\Sigma _p$, then we take this as a definition of (the complex points of) $Sh_{K_T}(G_T)$ and $Sh_{U_T}(H_T)$.
Following [Reference Diamond, Kassei and SasakiDKS23], we will study the relation between the top left and the top right space of the above diagram. To do so, we introduce the following notion, borrowed from [Reference Diamond, Kassei and SasakiDKS23, § 2.3.1].
Definition 3.2.2 We say that $K_E$ is sufficiently small with respect to $K_T$ if the following conditions are satisfied:
(i) $E^\times \cap \{ {y}/{y^c} \mid y \in K_E\}=\{1\}$;
(ii) $K_E\cap T_F({\mathbb {A}}_f)\subset K_T$;
(iii) $N_{E/F}(K_E)\subset \mathrm {Nm}(K_T)$.
3.2.3
Given $K_T$, it is always possible to choose $K_E$ sufficiently small with respect to $K_T$, cf. [Reference Diamond, Kassei and SasakiDKS23, § 2.3.1]. The main point is that the norm map ${\mathcal {O}}_E^\times \rightarrow {\mathcal {O}}_F^\times$ has finite kernel, hence we can choose $K_E$ satisfying the first condition. Note that this can be done independently of $K_T$; given $K_T$, we can then shrink $K_E$ so that it satisfies the second and third conditions. Furthermore, we may choose $K_E$ of the form $(\mathcal {O}_E\otimes {\mathbb {Z}}_p)^\times K_E^{p}$ (if $K_T$ is as in § 3.1.1).
3.2.4 Hecke algebras
Let $u: G_T \rightarrow H_T$ be the composite of the inclusion $G_T \rightarrow G_T \times T_E$ (whose second component is the composition of the structure map and the identity section) and the projection $G_T \times T_E \rightarrow H_T$. If $U_T \subset H_T({\mathbb {A}}_f)$ contains the image of $K_T \times K_E$, then $u$ induces a map $K_T\backslash G_T({\mathbb {A}}_f)/K_T \rightarrow U_T\backslash H_T({\mathbb {A}}_f)/U_T$, which, in turn, induces a (set theoretic) pullback map $r: \mathbb {T}_{U_T}(H_T)\rightarrow \mathbb {T}_{K_T}(G_T)$. On the other hand, the inclusion $G_T \rightarrow G_T \times T_E$ gives rise to a morphism of Hecke algebras $i: \mathbb {T}_{K_T}(G_T) \rightarrow \mathbb {T}_{U_T}(H_T)$ sending the characteristic function of a double coset $K_TgK_T$ to that of $U_T(g, 1)U_T$.
Lemma 3.2.5 Assume that $K_E$ is sufficiently small with respect to $K_T$ and that $U_T$ is the image of $K_T \times K_E$. Then the composite $r \circ i: \mathbb {T}_{K_T}(G_T)\rightarrow \mathbb {T}_{K_T}(G_T)$ is the identity.
Proof. Let us see $G_T$ as a subgroup of $G_T \times T_E$ and denote by $q:(G_T \times T_E)(\mathbb {A}_f)\rightarrow H_T(\mathbb {A}_f)$ the quotient map. Given $g \in G_T(\mathbb {A}_f)$, we need to prove that
Take $x$ belonging to the set on the left-hand side above. Then there exist $(k_1, e_1), (k_2, e_2) \in K_T \times K_E$ and $a \in T_F(\mathbb {A}_f)$ such that
As $x \in G_T(\mathbb {A}_f)$, we must have $a^{-1}e_1e_2=1$, hence $e_1e_2=a \in T_F(\mathbb {A}_f)\cap K_E\subset K_T$. It follows that
3.2.6
The above lemma implies, in particular, that the map $i: \mathbb {T}_{K_T}(G_T) \rightarrow \mathbb {T}_{U_T}(H_T)$ is injective. In what follows, we will use this map to identify $\mathbb {T}_{K_T}(G_T)$ with a sub-algebra of $\mathbb {T}_{U_T}(H_T)$. We will work with the Hecke algebra $\mathbb {T}=\bigotimes _{v}'{\mathbb {Z}}[\operatorname {GL}_2({\mathcal {O}}_v)\backslash \operatorname {GL}_2(F_v)/\operatorname {GL}_2({\mathcal {O}}_v)]$ as in $\S ~$2.1.2, where the product runs over the set of places of $F$ lying above a rational prime different from $p$ and such that the component of $K_T$ at $v$ is hyperspecial.
The statements in the next lemma are established, in a slightly different setting, in the proof of [Reference Diamond, Kassei and SasakiDKS23, Lemma 2.3.1].
Lemma 3.2.7 Assume that $K_E$ is sufficiently small with respect to $K_T$ and that $U_T$ is the image of $K_T \times K_E$. Then we have the following.
(i) The map $C_{K_T}\rightarrow C_{U_T}$ obtained composing the bottom arrows in (3.2.1.1) is injective.
(ii) The map $j: Sh_{K_T}(G_T)({\mathbb {C}})\rightarrow Sh_{U_T}(H_T)({\mathbb {C}})$ obtained composing the top arrows in (3.2.1.1) restricts to an isomorphism between each connected component of $Sh_{K_T}(G_T)({\mathbb {C}})$ and a connected component of the target.
Proof. For the reader's convenience, let us briefly explain how the main points of the argument in the proof of [Reference Diamond, Kassei and SasakiDKS23, Lemma 2.3.1] adapt to our situation.
(i) This follows from the fact that the inclusion $T_F\rightarrow T_{H_T}$ sending $a$ to $(a, 1)$ is split by the map $(a, b) \mapsto aN_{E/F}(b)$, which induces splittings
(note that the last formula gives a well-defined map $\mathrm {N}_{H_T}(U_T) \rightarrow \mathrm {Nm}(K_T)$ because of the assumptions that $U_T$ is the image of $K_T \times K_E$ and $N_{E/F}(K_E)\subset \mathrm {Nm}(K_T)$) of the inclusions
(ii) If $T=\Sigma _p$, there is nothing to prove. Assume that $T \neq \Sigma _p$. Then the claim follows from the equality, valid for every $g \in G_T({\mathbb {A}}_f)$:
Clearly the group on the left-hand side is contained in the group on the right-hand side. Conversely, let $h \in H_T({\mathbb {Q}})^+\cap g U_T g^{-1}$. On the one hand, we can write (the equivalence class of) $h$ as $h=a \cdot e$ for some $a \in G_T({\mathbb {Q}})^+, e \in E^\times$; on the other hand, $h=g(k \cdot y)g^{-1}$ for some $k \in K_T, y \in K_E$. It follows that $ae=g(ky)g^{-1}$, which implies that $e\cdot c(e)^{-1}=y\cdot c(y)^{-1} \in E^\times \cap \{ {y}/{y^c} \mid y \in K_E\}=\{1\}$. Therefore, $y \in K_E \cap T_F({\mathbb {A}}_f)\subset K_T$. This yields $h \in G_T({\mathbb {Q}})^+\cap g K_T g^{-1}$.
3.2.8
Keeping the notation and assumptions of the previous lemma, we set $I:=C_{U_T}/C_{K_T}$. For each $\alpha \in I$, let $Sh_{U_T}^{\alpha }(H_T)({\mathbb {C}}) \subset Sh_{U_T}(H_T)({\mathbb {C}})$ be the subspace consisting of connected components mapping to the $C_{K_T}$-coset inside $C_{U_T}$ given by $\alpha$. We obtain a decomposition
into open and closed subspaces; the subspace corresponding to the coset containing the identity is identified with $Sh_{K_{T}}(G_T)({\mathbb {C}})$ (if $\Sigma _p=T$, cf. the argument in the second part of the proof of [Reference Diamond, Kassei and SasakiDKS23, Lemma 2.3.1]).
Corollary 3.2.9 Assume that $K_E$ is sufficiently small with respect to $K_T$ and that $U_T$ is the image of $K_T \times K_E$. Let $\mathfrak {m}\subset \mathbb {T}$ be a maximal ideal and $i \geq 0$ an integer. Then:
(i) $H^i(Sh_{K_T}(G_{T}), {\mathbb {F}}_{\ell })_{\mathfrak {m}}\neq 0$ if and only if $H^i(Sh_{U_T}(H_T), {\mathbb {F}}_{\ell })_{\mathfrak {m}}\neq 0$, and the same assertion is true for the cohomology with ${\mathbb {Q}}_{\ell }$-coefficients;
(ii) the natural map $H^i_c(Sh_{U_T}(H_T), {\mathbb {F}}_{\ell })_\mathfrak {m}\rightarrow H^i(Sh_{U_T}(H_T), {\mathbb {F}}_{\ell })_\mathfrak {m}$ is an isomorphism if and only if the same is true for the map $H^i_c(Sh_{K_T}(G_{T}), {\mathbb {F}}_{\ell })_{\mathfrak {m}}\rightarrow H^i(Sh_{K_T}(G_{T}), {\mathbb {F}}_{\ell })_{\mathfrak {m}}$.
Proof. We will work over the complex numbers throughout this proof, and omit this from the notation for simplicity. The decomposition $Sh_{U_T}(H_T)=\coprod _{\alpha \in I} Sh_{U_T}^{\alpha }(H_T)$ introduced above yields a direct sum decomposition
and each summand on the right-hand side is preserved by the action of $\mathbb {T}$. Indeed, the Hecke algebra $\mathbb {T}$ is spanned by characteristic functions of double cosets $K_TgK_T$, whose component at a place $v$ is of the form $\operatorname {GL}_2(\mathcal {O}_v)\big (\begin{smallmatrix} \varpi _v^{a_v} & 0\\ 0 & \varpi _v^{b_v} \end{smallmatrix}\big )\operatorname {GL}_2(\mathcal {O}_v)$, for some uniformiser $\varpi _v$ of $\mathcal {O}_v$ and $a_v, b_v \in {\mathbb {Z}}$. The group $K_E$ is sufficiently small with respect to $K_{T, g}:=K_T \cap gK_Tg^{-1}$; letting $U_{T, g}\subset H_T(\mathbb {A}_f)$ be the image of $K_{T, g} \times K_E$ (which coincides with the group $U_{T} \cap gU_Tg^{-1}$), the Hecke correspondence
restricts to a correspondence on each $Sh_{U_T}^{\alpha }(H_T)$. Indeed, the map $Sh_{U_{T, g}}(H_T)\rightarrow Sh_{U_{T, g^{-1}}}(H_T)$ induced by right multiplication by $(g, 1) \in H_T({\mathbb {A}}_f)$ preserves each $Sh_{U_{T, g}}^\alpha (H_T)$, as $N_{H_T}((g, 1)) \in {\mathbb {A}}_{F, f}^\times \subset T_{H_T}({\mathbb {A}}_f)$. Hence, each summand in (3.2.9.1) is preserved by the action of $\mathbb {T}$.
On the other hand, we have an action of $T_E(\mathbb {A}_f)$ on $Sh_{U_T}(H_{T})$: the action of $e \in T_E(\mathbb {A}_f)$ sends each $Sh_{U_T}^{\alpha }(H_T)$ to $Sh_{U_T}^{e\alpha }(H_T)$. In particular, $T_E(\mathbb {A}_f)$ acts transitively on the set of subvarieties $Sh_{U_T}^{\alpha }(H_T)$, inducing isomorphisms, for every $\alpha \in I$:
Finally, the action on cohomology induced by the $T_E(\mathbb {A}_f)$-action on $Sh_{U_T}(H_{T})$ commutes with the action of $\mathbb {T}$. It follows that the above isomorphism induces an isomorphism
The isomorphism (3.2.9.2) (which also holds with ${\mathbb {Q}}_\ell$-coefficients) implies part (i). Furthermore, the previous argument also applies to compactly supported cohomology, yielding a direct sum decomposition of $H^i_c(Sh_{U_T}(H_T), {\mathbb {F}}_{\ell })_\mathfrak {m}$ as in (3.2.9.2). Hence we obtain a similar decomposition for the kernel and cokernel of the map $H^i_c(Sh_{U_T}(H_T), {\mathbb {F}}_{\ell })_\mathfrak {m}\rightarrow H^i(Sh_{U_T}(H_T), {\mathbb {F}}_{\ell })_\mathfrak {m}$, from which part (ii) follows.
3.3 Integral models of unitary Shimura varieties
3.3.1
Fix a totally negative element $\mathfrak {d} \in \mathcal {O}_F$ coprime to $p$; choose isomorphisms $\theta _T: M_2(E)=D_{\emptyset } \buildrel \sim \over \to D_{T}$ for every non-empty subset $T \subset \Sigma _p$. For every such $T$, choose an element $\delta _T \in D_T$ as in [Reference Tian and XiaoTX16, Lemma 3.8], and let $\sigma _T=\sqrt {\mathfrak {d}}\delta _T$. Via the construction in § 3.1.3, such a choice gives an involution $*_T$ on each $D_T$. By [Reference Tian and XiaoTX16, Lemma 5.4] we may, and will, choose the elements $\delta _T$ in such a way that these involutions are respected by the isomorphisms $\theta _T$. Let $\mathcal {O}_{D_\emptyset }=M_2(\mathcal {O}_E)\subset D_{\emptyset }$ and $\mathcal {O}_{D_T}=\theta _T(\mathcal {O}_{D_\emptyset })$ for every non-empty subset $T \subset \Sigma _p$.
Take $K_T\subset G_T(\mathbb {A}_f)$ as in § 3.1.1, $K_E=(\mathcal {O}_E\otimes {\mathbb {Z}}_p)^\times K_E^{p} \subset T_E({\mathbb {A}}_f)$ sufficiently small with respect to $K_T$ and let $U_T\subset H_T(\mathbb {A}_f)$ be the image of $K_T \times K_E$. The inverse of the chosen isomorphism $\iota _p: \bar {{\mathbb {Q}}}_p \buildrel \sim \over \to {\mathbb {C}}$ determines a distinguished $p$-adic place $\wp$ of the reflex field $E_T \subset {\mathbb {C}}$. Let $E_\wp \subset \bar {{\mathbb {Q}}}_p$ be the completion of $E_T$ at $\wp$, and ${\mathcal {O}}_\wp$ its ring of integers. Following [Reference Diamond, Kassei and SasakiDKS23, § 2] and [Reference Tian and XiaoTX16, § 3], an integral model of $Sh_{U_T}(H_T)$ over ${\mathcal {O}}_\wp$ can be constructed as follows. Consider the functor sending an ${\mathcal {O}}_\wp$-scheme $S$ to the set of isomorphism classes of tuples $(A, \iota, \lambda, \eta )$ where:
(i) $A/S$ is an abelian scheme of dimension $4g$;
(ii) $\iota : \mathcal {O}_{D_T}\rightarrow \mathrm {End}_S(A)$ is an embedding;
(iii) $\lambda : A \rightarrow A^\vee$ is a ${\mathbb {Z}}_{(p)}^\times$-polarisation whose attached Rosati involution coincides with $*_T$ on $\mathcal {O}_{D_T}$;
(iv) $\eta$ is a $U_T$-level structure, in the sense of [Reference Diamond, Kassei and SasakiDKS23, § 2.2.2].
Furthermore, the above data are required to satisfy the following conditions.
(a) For every $b \in \mathcal {O}_E$, the characteristic polynomial of $\iota (b)$ acting on $\mathrm {Lie}(A/S)$ equals
\[ \prod_{\tilde{\tau} \in \Sigma_{E, \infty}}(X-\tilde{\tau}(b))^{2s_{\tilde{\tau}}}, \]where the integers $s_{\tilde {\tau }}$ were defined in § 3.1.2.(b) The kernel $\ker (\lambda [p^\infty ]): A[p^\infty ]\rightarrow A^\vee [p^\infty ]$ is a finite flat subgroup scheme contained in $\prod _{\mathfrak {p} \in T}A[\mathfrak {p}]$ and such that for each $\mathfrak {p} \in T$ the rank of $\ker (\lambda [p^\infty ])\cap A[\mathfrak {p}]$ is $p^4$.
(c) The cokernel of $\lambda _*: H_1^{dR}(A/S)\rightarrow H_1^{dR}(A^\vee /S)$ is locally free of rank two over $\bigoplus _{\mathfrak {p} \in T} \mathcal {O}_S\otimes _{{\mathbb {Z}}_p} (\mathcal {O}_E\otimes _{\mathcal {O}_F}\mathcal {O}_F/\mathfrak {p})$ (here $H_1^{dR}(A/S)$ denotes the de Rham homology sheaf of $A/S$).
This functor is represented by a scheme $Y_{U_T}(H_T)$ which is an infinite disjoint union of smooth, quasi-projective (respectively, projective if $T$ is non-empty) ${\mathcal {O}}_\wp$-schemes. The group $\mathcal {O}_{F, (p)}^{\times, +}$ acts on this scheme as follows: an element $u \in \mathcal {O}_{F, (p)}^{\times, +}$ sends $(A, \iota, \lambda, \eta )$ to $(A, \iota, u\lambda, \eta )$. This action factors through the group $\mathcal {O}_{F, (p)}^{\times, +}/N_{E/F}(U_T \cap E^\times )$, and the resulting quotient is a smooth quasi-projective scheme giving the desired integral model of $Sh_{U_T}(H_T)$.
Remark 3.3.2 (i) More precisely, the above description of the moduli problem, using the level structure as in [Reference Diamond, Kassei and SasakiDKS23, § 2.2.2], is valid for locally noetherian schemes $S$. We will need later on to work with non-locally noetherian schemes as well; in this case, one can use a different definition of the level structure, adapting [Reference LanLan18, Definition 1.3.7.6].
(ii) For any field extension $L$ of $E_T$, one can define schemes $Y_{U_T}(H_T)_L$ over $\mathrm {Spec} \, L$ for arbitrary $U_T=U_T^pU_{T, p}$ representing a moduli problem as above, including $U_{T, p}$-level structure.
Remark 3.3.3 Note that, if $S$ is the spectrum of a ring where $p$ is nilpotent, then conditions (a), (b) and (c) in the definition of the above moduli problem can be stated in terms of the $p$-divisible group (with $\mathcal {O}_E$-action) of the abelian scheme $A$. Indeed, by [Reference MessingMes72, p. 164] the Lie algebra of $A/S$ (respectively, of the universal vector extension of $A/S$) is isomorphic to the Lie algebra of $A[p^\infty ]$ (respectively, of the universal vector extension of $A[p^\infty ]$). Hence, the first condition is the Kottwitz condition on $A[p^\infty ]$; the second condition manifestly only depends on $A[p^\infty ]$, and the same is true for the third, as the first de Rham cohomology of $A/S$ is identified with the Lie algebra of the universal vector extension of the dual of $A$ by [Reference Mazur and MessingMM06, Chapter 1, § 4].
4. Comparison of unitary Igusa varieties
In this section, we establish an isomorphism between Igusa varieties that are a priori attached to different unitary Shimura varieties. This relies on a reinterpretation of (some of) the arguments in [Reference Tian and XiaoTX16] in the case of a totally split prime.
4.1 Kottwitz sets
We keep the notation introduced in the previous section. In particular, we fixed in § 3.1.1 a prime $p$ which splits completely in $F$; hence, we can write $D_T\otimes _{{\mathbb {Q}}}{\mathbb {Q}}_p=\prod _{\mathfrak {p} \in \Sigma _p}D_{T, \mathfrak {p}}$ and $H_{T, {\mathbb {Q}}_p}:=H_T \times _{\mathbb {Q}} {\mathbb {Q}}_p=\prod _{\mathfrak {p} \in \Sigma _p}H_{T, \mathfrak {p}}$, where $D_{T, \mathfrak {p}}:=D_T\otimes _F F_\mathfrak {p}$ and, for every $F_\mathfrak {p}-$algebra $R$,
According to [Reference Tian and XiaoTX16, Lemma 3.8], the subgroup defined by
is an unramified (respectively, non-quasi-split) group over $F_\mathfrak {p}$ if $\mathfrak {p} \in \Sigma _p \smallsetminus T$ (respectively, $\mathfrak {p} \in T$). Furthermore, the natural maps $G_T \leftarrow G_T \times T_E \rightarrow H_T$ are compatible with the Deligne homomorphisms and induce isomorphisms of derived and adjoint groups. Denoting by $\mu _T$ the cocharacter of $H_{T, \bar {{\mathbb {Q}}}_p}$ induced by $(H_T, X_T)$ and by the isomorphism $\iota _p$, we have the Kottwitz set $B(H_{T, {\mathbb {Q}}_p}, \mu _T)$. We can write $B(H_{T, {\mathbb {Q}}_p}, \mu _T)=\prod _{\mathfrak {p} \in \Sigma _p} B(H_{T, \mathfrak {p}}, \mu _{T, \mathfrak {p}})$, where $\mu _{T, \mathfrak {p}}$ is the $\mathfrak {p}$-component of $\mu _T$, and it follows from [Reference KottwitzKot97, (6.5.1), (6.5.2)] that $B(H_{T, \mathfrak {p}}, \mu _{T, \mathfrak {p}})$ can be described as follows:
(i) it contains two elements, the basic one and the $\mu$-ordinary one, if $\mathfrak {p} \in \Sigma _p \smallsetminus T$;
(ii) it is a singleton if $\mathfrak {p} \in T$.
Let $b=(b_\mathfrak {p})_{\mathfrak {p} \in \Sigma _p} \in B(H_{T, {\mathbb {Q}}_p}, \mu _T)$ and let $B \subset \Sigma _p \smallsetminus T$ be the set of places such that $b_\mathfrak {p}$ is basic. Let $T':=T \coprod B$ and $b' \in B(H_{T', {\mathbb {Q}}_p}, \mu _{T'})$ be the element which is $\mu$-ordinary at every place $\mathfrak {p} \in \Sigma _p \smallsetminus T'$. We call $b'$ the element in $B(H_{T', {\mathbb {Q}}_p}, \mu _{T'})$ associated with $b$.
4.2 Igusa varieties
Every $b \in B(H_{T, {\mathbb {Q}}_p}, \mu _T)$ corresponds to a Newton stratum in the special fibre of $Y_{U_T}(H_T)$, hence to a Newton stratum in the special fibre of $Sh_{U_T}(H_T)$. Let $(\mathbb {X}^b_T, \iota ^b_T, \lambda ^b_T)$ be a $p$-divisible group with extra structure attached to an $\bar {\mathbb {F}}_p$-point in such a stratum. Note that, as $p$ splits completely in $F$, this datum is equivalent to the datum of a collection of $p$-divisible groups with extra structure $(\mathbb {X}^{b_\mathfrak {p}}_T, \iota ^{b_\mathfrak {p}}_T, \lambda ^{b_\mathfrak {p}}_T)$, for each $\mathfrak {p} \in \Sigma _p$. Similarly, if $({\mathcal {G}}, \iota _{\mathcal {G}}, \lambda _{\mathcal {G}})$ is a $p$-divisible group with extra structure then an isomorphism (or, more generally, a quasi-isogeny) $\phi : \mathbb {X}^b_T \rightarrow \mathcal {G}$ commuting with the ${\mathcal {O}}_{D_T}$-action splits as a sum of isomorphisms (or quasi-isogenies) $\phi _\mathfrak {p}$ indexed by places $\mathfrak {p} \in \Sigma _p$. We will write $\phi =(\phi _\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}$.
4.2.1
Let $\overline {\mathrm {Ig}}_T^b$ be the scheme representing the functor that sends a ring $R$ of characteristic $p$ to the set of isomorphism classes of data $(r, A, \iota, \lambda, \eta, \phi )$ defined as follows:
(i) $r: \bar {\mathbb {F}}_p\rightarrow R$ is a ring morphism;
(ii) $(A, \iota, \lambda, \eta )/\mathrm {Spec} \, R$ is a datum as in the definition of the integral model of $Sh_{U_T}(H_T)$, satisfying conditions (a), (b) and (c) in § 3.3;
(iii) $\phi =(\phi _\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}: A[p^\infty ] \buildrel \sim \over \to \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p, r}R$ is an isomorphism commuting with the $\mathcal {O}_{D_T}$-action and such that each $\phi _\mathfrak {p}$ respects the polarisation up to a ${\mathbb {Z}}_p^\times$-factor.
Two tuples $(r, A, \iota, \lambda, \eta, \phi ), (r', A', \iota ', \lambda ', \eta ', \phi ')$ are said to be isomorphic if $r=r'$ and there is an isomorphism of abelian schemes over $\mathrm {Spec} \, R$ between $A$ and $A'$ commuting with all the additional data.
Forgetting everything but the structure map $r$ we see that $\overline {\mathrm {Ig}}_T^b$ is fibred over $\bar {\mathbb {F}}_p$; in what follows, if there is no danger of confusion, we will abusively denote its points with values in an $\bar {\mathbb {F}}_p$-algebra $(R, r)$ just by $(A, \iota, \lambda, \eta, \phi ) \in \overline {\mathrm {Ig}}_T^b(R)$. The functor defining $\overline {\mathrm {Ig}}_T^b$ is representable: indeed, $\overline {\mathrm {Ig}}_T^b\rightarrow Y_{U_T}(H_T)_{\bar {\mathbb {F}}_p}$ relatively represents the moduli problem parametrising isomorphisms $\phi : A[p^\infty ]\buildrel \sim \over \to \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p, r}R$ as above. By definition, such an isomorphisms is a compatible sequence of isomorphisms $\phi _k: A[p^k]\buildrel \sim \over \to \mathbb {X}^b_T[p^k]\times _{\bar {\mathbb {F}}_p, r}R$ for $k \geq 0$. Hence $\overline {\mathrm {Ig}}_T^b$ is the inverse limit of the schemes $\overline {\mathrm {Ig}}_{T, k}^b\rightarrow Y_{U_T}(H_T)_{\bar {\mathbb {F}}_p}$ parametrising isomorphisms $\phi _k$ as above; each of these moduli problems is relatively representable (cf. [Reference Caraiani and ScholzeCS17, Proposition 4.3.3]) and the transition maps are finite.
Recall that we have an action of ${\mathcal {O}}_{F, (p)}^{\times, +}$ on $Y_{U_T}(H_T)_{\bar {\mathbb {F}}_p}$. For each $k \geq 0$, consider the quotient $\Delta _k:=\mathcal {O}_{F, (p)}^\times /\{N_{E/F}(u), u \in U_T \cap \mathcal {O}_E^\times, u \equiv 1 \pmod {p^k}\}$; set $\Delta :=\varprojlim _k \Delta _k$. The action of $\mathcal {O}_{F, (p)}^{\times, +}$ on $\overline {\mathrm {Ig}}_{T, k}^b$ lifting the action on $Y_{U_T}(H_T)_{\bar {\mathbb {F}}_p}$ factors through $\Delta _k$, hence we get an action of $\Delta$ on $\overline {\mathrm {Ig}}_T^b$. We define $\mathrm {Ig}_T^b:=\overline {\mathrm {Ig}}_T^b/\Delta$.
For each $\mathfrak {p} \in \Sigma _p$ fix an element $x_\mathfrak {p} \in {\mathcal {O}}_F^+$ with $\mathfrak {p}$-adic valuation one, and with $\mathfrak {p}'$-adic valuation zero for every $\mathfrak {p}' \in \Sigma _p \smallsetminus \{\mathfrak {p}\}$. The following lemma gives a description of the functor of points of $\overline {\mathrm {Ig}}_T^b$ in terms of abelian schemes up to $p$-quasi-isogeny; see also [Reference Caraiani and ScholzeCS17, Lemma 4.3.4].
Lemma 4.2.2 Let $R$ be a ring of characteristic $p$. There is a bijection, functorial in $R$, between $\overline {\mathrm {Ig}}_T^b(R)$ and the set of isomorphism classes of data $(r, A, \iota, \lambda, \eta, \rho )$ defined as follows:
(i) $r: \bar {\mathbb {F}}_p\rightarrow R$ is a ring morphism;
(ii) $A$ is an abelian scheme of dimension $4g$ over $\mathrm {Spec} \, R$;
(iii) $\iota : \mathcal {O}_{D_T}\rightarrow \mathrm {End}_R(A)$ is an embedding;
(iv) $\lambda : A \rightarrow A^\vee$ is a ${\mathbb {Z}}_{(p)}^\times$-polarisation such that the attached Rosati involution coincides with $*_T$ on $\mathcal {O}_{D_T}$;
(v) $\eta$ is a level structure, defined as in § 3.3;
(vi) $\rho =(\rho _\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}: A[p^\infty ] \rightarrow \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p, r}R$ is a quasi-isogeny commuting with $\mathcal {O}_{D_T}$-action and such that each $\rho _\mathfrak {p}$ respects the polarisation up to a ${\mathbb {Q}}_p^\times$-factor.
Two tuples $(r, A, \iota, \lambda, \eta, \rho ), (r', A', \iota ', \lambda ', \eta ', \rho ')$ are regarded as isomorphic if $r=r'$ and there is a $p$-quasi-isogeny from $A$ to $A'$ commuting with $\mathcal {O}_{D_T}$-action, level structure and the quasi-isogenies $\rho, \rho '$, and respecting polarisations up to a product of integral powers of the elements $x_\mathfrak {p}$.
Remark 4.2.3 Before proving the lemma, let us comment on its content. The first point is that the datum $(A, \iota, \lambda, \eta )$ is not a priori required to satisfy the conditions (a), (b) and (c) in § 3.3; the second point is that the isomorphism $\phi$ in the definition of the moduli problem represented by $\overline {\mathrm {Ig}}_T^b$ is replaced by a quasi-isogeny $\rho$ (at the price of changing the notion of isomorphism of the data we are parametrising). Both points will be crucial in the next theorem.
Proof. Let $R$ be an $\bar {\mathbb {F}}_p$-algebra. An isomorphism class of data $(A, \iota, \lambda, \eta, \phi )$ corresponding to an $R$-point of $\overline {\mathrm {Ig}}_T^b$ gives rise to a tuple as in the statement of the lemma. Conversely, let $(A, \iota, \lambda, \eta, \rho )$ be a datum as in the statement of the lemma; multiplying $\rho$ by suitable powers of the elements $x_\mathfrak {p}$ we obtain an isogeny, abusively still denoted by the same symbol, $\rho : A[p^\infty ]\rightarrow \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p}R$, commuting with $\mathcal {O}_{D_T}$-action and polarisation (the latter up to a ${\mathbb {Q}}_p^\times$-factor on each component). Letting $B=A/\ker (\rho )$, the map $\rho$ induces an isomorphism $\bar {\rho }: B[p^\infty ]\xrightarrow {\sim } \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p}R$, and this property characterises uniquely $B$ among abelian schemes in the $p$-power isogeny class of $A$. In order to complete the proof we need to endow $B$ with extra structures $\iota _B, \lambda _B, \eta _B, \phi$ in such a way that $(B, \iota _B, \lambda _B, \eta _B, \phi )$ is a point of $\overline {\mathrm {Ig}}^b_T$, and the quotient map $q: A\rightarrow B$ respects the extra structures as in the statement of the lemma.
Let us start by defining the $\mathcal {O}_{D_T}$-action on $B$. Given $o \in \mathcal {O}_{D_T}$ we consider the self-quasi-isogeny $\iota _B(o):=q \circ \iota (o) \circ q^{-1}$ of $B$. Let us look at the following diagram.
By assumption, the largest square and the left square in the diagram commute; it follows that the right square also commutes. We deduce that $\iota _B(o): B \rightarrow B$ is a morphism (and not just a quasi-isogeny) as the same is true for $\iota _T^b(o): \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p}R \rightarrow \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p}R$. Hence, the map sending $o$ to $\iota _B(o)$ endows $B$ with an $\mathcal {O}_{D_T}$-action, which commutes with the quotient map $A \rightarrow B$ by construction.
Let us now define the polarisation $\lambda _B$. We consider the quasi-isogeny $\lambda '_B:=(q^\vee )^{-1}\circ \lambda \circ q^{-1}: B \rightarrow B^\vee$. It fits in the following diagram.
By assumption, the map $\rho =\bar {\rho }\circ q$ can be written as $\rho =(\rho _\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}$ where each $\rho _\mathfrak {p}$ respects polarisations on the $\mathfrak {p}$-component of the relevant $p$-divisible groups up to a factor $c_\mathfrak {p} \in {\mathbb {Q}}_p^\times$, i.e. we have $(\rho _\mathfrak {p}^\vee )^{-1} \circ \lambda _\mathfrak {p} \circ (\rho _\mathfrak {p})^{-1}=c_\mathfrak {p}\lambda _{\mathbb {X}^{b_\mathfrak {p}}_T}$. For each $\mathfrak {p}$ let $v_\mathfrak {p}$ be the valuation of $c_\mathfrak {p}$, and set $\lambda _B:=(\prod _{\mathfrak {p} \in \Sigma _p} x_\mathfrak {p}^{-v_\mathfrak {p}})\lambda '_B$; then the isomorphism $\bar {\rho }$ commutes with the polarisations $\lambda _B$ and $\lambda _{\mathbb {X}^b_T}$ up to a ${\mathbb {Z}}_p^\times$-factor on each component.
Let $\eta _B$ be the (prime to $p$) level structure on $B$ induced by $\eta$ and $q$. Let the isomorphism $\phi$ be given by $\bar {\rho }$. Note that changing the polarisation on $A$ by a product of powers of the elements $x_\mathfrak {p}$ does not affect the polarisation $\lambda _B$, hence the isomorphism class of $(B, \iota _B, \lambda _B, \eta _B, \phi )$ only depends on the isomorphism class of $(A, \iota, \lambda, \eta, \rho )$ (in the sense of the lemma).
Furthermore, by construction, the map $q$ commutes with polarisations up to a product of powers of the elements $x_\mathfrak {p}$, and respects all the other additional structures; therefore, the data $(A, \iota, \lambda, \eta, \rho )$ and $(B, \iota _B, \lambda _B, \eta _B, \phi )$ are isomorphic in the sense of the lemma.
Finally, the datum $(B, \iota _B, \lambda _B, \eta _B)$ satisfies conditions (a), (b) and (c) in § 3.3, hence is a point of $\overline {\mathrm {Ig}}_T^b$. This follows from Remark 3.3.3 and from the fact that the $p$-divisible group $\mathbb {X}^b_T$ comes from an abelian variety with extra structure satisfying the same conditions.
Theorem 4.2.4 Let $b \in B(H_{T, {\mathbb {Q}}_p}, \mu _T)$ and let $B\subset \Sigma _p \smallsetminus T$ be the subset of places $\mathfrak {p}$ such that $b_\mathfrak {p}$ is basic. Let $T'=T \coprod B$ and let $b' \in B(H_{T', {\mathbb {Q}}_p}, \mu _{T'})$ be the element associated with $b$. Then there is an isomorphism
whose induced map in cohomology is equivariant with respect to the action of the Hecke operators outside $p$.
Proof. It suffices to produce an isomorphism $\overline {\mathrm {Ig}}^b_T \simeq \overline {\mathrm {Ig}}^{b'}_{T'}$ which satisfies the requirements in the theorem and is in addition ${\mathcal {O}}_{F, (p)}^{\times, +}$-equivariant. Recall that in § 3.3 we have chosen isomorphisms
i.e. isomorphisms $\theta _T: D_\emptyset \buildrel \sim \over \to D_T$ respecting orders and involutions; we use these isomorphisms to identify the above data, and we denote them by $(D, *, \mathcal {O}_D)$ in this proof. With this notation, Lemma 4.2.2 tells us that, for every $T \subset \Sigma _p$ and every $\bar {\mathbb {F}}_p$-algebra $R$, the set $\overline {\mathrm {Ig}}_T^b(R)$ is the set of isomorphism classes of data $(A, \iota, \lambda, \eta, \rho )$ where:
(i) $A/\mathrm {Spec} \, R$ is an abelian scheme of dimension $4g$;
(ii) $\iota : \mathcal {O}_{D}\rightarrow \mathrm {End}_R(A)$ is an embedding;
(iii) $\lambda : A \rightarrow A^\vee$ is a ${\mathbb {Z}}_{(p)}^\times$ polarisation whose attached Rosati involution coincides with $*$ on $\mathcal {O}_{D}$;
(iv) $\eta$ is a level structure, defined as in § 3.3;
(v) $\rho : A[p^\infty ]\rightarrow \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p}R$ is a quasi-isogeny commuting with $\mathcal {O}_{D}$-action and polarisation (the latter up to a constant).
In particular, the only datum in the description of the functor of points of $\overline {\mathrm {Ig}}_T^b$ which depends on $T$ is the quasi-isogeny $\rho : A[p^\infty ]\rightarrow \mathbb {X}^b_T\times _{\bar {\mathbb {F}}_p}R$. Hence, in order to complete the proof it suffices to show that, if $b$ is associated with $b'$, then there is a quasi-isogeny $\rho _{T, T'}: \mathbb {X}^b_T\rightarrow \mathbb {X}^{b'}_{T'}$ commuting with the extra structure. The functor sending $(A, \iota, \lambda, \eta, \rho )$ to $(A, \iota, \lambda, \eta, \rho _{T, T'}\circ \rho )$ will then give the desired isomorphism $\overline {\mathrm {Ig}}^b_T \simeq \overline {\mathrm {Ig}}^{b'}_{T'}$; as ${\mathcal {O}}_{F, (p)}^{\times, +}$ only acts modifying polarisations by prime to $p$ quasi-isogenies, this isomorphism is ${\mathcal {O}}_{F, (p)}^{\times, +}$-equivariant. The existence of a quasi-isogeny $\rho _{T, T'}$ as above follows from the construction in the proof of [Reference Tian and XiaoTX16, Lemma 5.18]. Indeed, letting ${\mathcal {D}}_T$ be the Dieudonné module of $\mathbb {X}^b_T$, the argument in [Reference Tian and XiaoTX16, proof of Lemma 5.18, p. 2185] produces a Dieudonné module $p{\mathcal {D}}_T \subset N \subset {\mathcal {D}}_T$, giving rise to a closed finite subgroup scheme $Z\subset \mathbb {X}^b_T[p]$; moreover $\mathbb {X}^b_T/Z$ is isomorphic to $\mathbb {X}^{b'}_{T'}$, and the construction in [Reference Tian and XiaoTX16, proof of Lemma 5.18, p. 2185] endows the quotient $\mathbb {X}^b_T/Z$ with extra structures respected by the isogeny $\mathbb {X}^b_T/Z\rightarrow \mathbb {X}^b_T$ whose composite with the quotient map is multiplication by $p$.
Remark 4.2.5 (i) The argument in [Reference Tian and XiaoTX16, p. 47] mentioned above constructs $N$ starting from the unitary Dieudonné module of $\mathbb {X}^b_T$ and using the Frobenius operator; a key point is that this results in a change of signature. The reader may find it helpful to check directly this phenomenon in the explicit examples given in [Reference Bültel and WedhornBW06, (3.2)].
(ii) With the notation as in the above theorem, the main result of [Reference Tian and XiaoTX16] implies that the Newton strata indexed by $b$ and $b'$ in the special fibres of the Shimura varieties attached to $H_T$ and $H_{T'}$ are isomorphic. The above result shows that the same is true for the corresponding Igusa varieties. This is natural to expect, in view of Lemma 4.2.2 and of the fact that the isomorphism in [Reference Tian and XiaoTX16] is obtained from a quasi-isogeny on the level of $p$-divisible groups. The existence of such isomorphisms between Igusa varieties is established much more systematically in the function field setting in Sempliner's PhD thesis.
5. The geometry of the Hodge–Tate period morphism
The goal of this section is to establish the infinite-level Mantovan product formula for our abelian-type unitary Shimura varieties. As a consequence, we can compute the fibers of the Hodge–Tate period morphism in terms of Igusa varieties.
5.1 The product formula
Take $p$ as in the previous section and choose a subset $T \subset \Sigma _p$; in order to simplify the notation, unless otherwise stated we will keep $T$ fixed throughout this section, and omit it from the notation. Fix an element $b=(b_\mathfrak {p})_{\mathfrak {p} \in \Sigma _p} \in B(H_{{\mathbb {Q}}_p}, \mu )$, and let $(\mathbb {X}^b, \iota ^b, \lambda ^b)$ be a $p$-divisible group with extra structure attached to $b$, giving rise to a collection of $p$-divisible groups with extra structure $(\mathbb {X}^{b_\mathfrak {p}}, \iota ^{b_\mathfrak {p}}, \lambda ^{b_\mathfrak {p}})$, for $\mathfrak {p} \in \Sigma _p$, as in the previous section.
5.1.1
Let $\breve {{\mathcal {O}}}_\wp$ be the ring of integers of the completion of the maximal unramified extension of $E_\wp$, and let $\mathrm {Nilp}_{\breve {{\mathcal {O}}}_\wp }$ be the category of $\breve {{\mathcal {O}}}_\wp$-algebras in which $p$ is nilpotent. Following [Reference Caraiani and ScholzeCS17, Definition 4.3.11], we consider the functor $\mathfrak {X}^b: \mathrm {Nilp}_{\breve {{\mathcal {O}}}_\wp } \rightarrow \mathrm {Sets}$ sending $R$ to the set of isomorphism classes of data $(A, \iota, \lambda, \eta, \varphi )$, where:
(i) $(A, \iota, \lambda, \eta )/\mathrm {Spec} \, R$ is a datum as in § 3.3; and
(ii) $\varphi =\bigoplus _{\mathfrak {p} \in \Sigma _p}\varphi _\mathfrak {p}: A[p^\infty ]\times _{R} R/p=\bigoplus _{\mathfrak {p} \in \Sigma _p}A[\mathfrak {p}^\infty ]\times _{R} R/p\rightarrow \bigoplus _{\mathfrak {p} \in \Sigma _p} \mathbb {X}^{b_\mathfrak {p}}\times _{\bar {\mathbb {F}}_p}R/p$ is a quasi-isogeny commuting with the ${\mathcal {O}}_D$-action, and such that each $\varphi _\mathfrak {p}$ respects the polarisation up to a ${\mathbb {Q}}_p^\times$-factor.
We will now decompose $\mathfrak {X}^b$ as a product of Rapoport–Zink spaces and a formal lift of an Igusa variety we introduced before, as in [Reference Caraiani and ScholzeCS17, Lemma 4.3.12]. The existence of such lifts is a consequence of the next lemma, which is analogous to [Reference Caraiani and ScholzeCS17, Corollary 4.3.5].
Lemma 5.1.2 The scheme $\overline {\mathrm {Ig}}^b$ is perfect.
Proof. We have to show that, for every ring $R$, the absolute Frobenius $\mathrm {Fr}: \overline {\mathrm {Ig}}^b \rightarrow \overline {\mathrm {Ig}}^b$ induces a bijection on $R$-points. We will use the description of the functor of points of $\overline {\mathrm {Ig}}^b$ given in Lemma 4.2.2. As the map $\mathrm {Fr}$ is not a morphism of $\bar {\mathbb {F}}_p$-schemes, in this proof we need to take the $\bar {\mathbb {F}}_p$-algebra structure on $R$ into account. Let $(r, A, \iota, \lambda, \eta, \rho )$ be an $R$-point of $\overline {\mathrm {Ig}}^b$; its image via Frobenius is the $R$-point $(r^{(p)}, A^{(p)}, \iota ^{(p)}, \lambda ^{(p)}, \eta ^{(p)}, \rho ^{(p)})$ where:
(i) $r^{(p)}$ is the composite of $r$ and the Frobenius on $\bar {\mathbb {F}}_p$;
(ii) $A^{(p)}:=A \times _{R, \mathrm {Fr}_R}R$;
(iii) ($\iota ^{(p)}, \lambda ^{(p)}, \eta ^{(p)}$) are induced from $(\iota, \lambda, \eta )$ by functoriality;
(iv) $\rho ^{(p)}:=\rho \times \mathrm {Id}: A[p^\infty ] \times _{R, \mathrm {Fr}_R}R \rightarrow (\mathbb {X}^b\times _{\overline {\mathbb {F}}_p, r} R) \times _{R, \mathrm {Fr}_R} R = \mathbb {X}^b\times _{\overline {\mathbb {F}}_p, r^{(p)}} R$.
Let $F_A: A \rightarrow A^{(p)}$ be the relative Frobenius morphism. Then $F_A$ commutes with $\iota, \iota ^{(p)}$ (as well as with the level structures) by functoriality. Furthermore, we have
where the first equality holds true by functoriality of relative Frobenius and the second follows from the fact that $(F_A)^\vee$ is the Verschiebung on $A^\vee$, and the composite of Verschiebung and Frobenius is multiplication by $p$. Finally, we have
where $F_{\mathbb {X}^b}: \mathbb {X}^b \times _{\overline {\mathbb {F}}_p, r} R \rightarrow \mathbb {X}^b \times _{\overline {\mathbb {F}}_p, r^{(p)}} R$ is the relative Frobenius. Writing $\prod _{\mathfrak {p} \in \Sigma _p}x_\mathfrak {p}=pt$ with $t \in {\mathcal {O}}_{F, (p)}^{\times, +}$, we deduce that the $R$-point $(r^{(p)}, A^{(p)}, \iota ^{(p)}, \lambda ^{(p)}, \eta ^{(p)}, \rho ^{(p)})$ coincides with the $R$-point
Let us denote by $r^{(-p)}$ the composition of $r$ and the inverse of Frobenius on $\overline {\mathbb {F}}_p$; we have the Verschiebung map $V_{\mathbb {X}^b}: \mathbb {X}^b \times _{\bar {\mathbb {F}}_p, r} R \rightarrow \mathbb {X}^b \times _{\bar {\mathbb {F}}_p, r^{(-p)}} R$, and the map $\overline {\mathrm {Ig}}^b \rightarrow \overline {\mathrm {Ig}}^b$ which on $R$-points is given by
is the inverse of the map induced by $\mathrm {Fr}: \overline {\mathrm {Ig}}^b \rightarrow \overline {\mathrm {Ig}}^b$.
5.1.3 The formal Igusa variety
Since the Igusa variety $\overline {\mathrm {Ig}}^b$ is perfect, it lifts canonically to a flat $p$-adic formal scheme $\overline {\mathfrak {Ig}}^b: \mathrm {Nilp}_{\breve {{\mathcal {O}}}_\wp } \rightarrow \mathrm {Sets}$ described as follows (see [Reference Caraiani and ScholzeCS17, p. 719]): fix a lift (up to quasi-isogeny) $\hat {\mathbb {X}}^{b}/\breve {{\mathcal {O}}}_\wp$ of $\mathbb {X}^b$ with extra structure. For $R \in \mathrm {Nilp}_{\breve {{\mathcal {O}}}_\wp }$, the $R$-points of $\overline {\mathfrak {Ig}}^b$ are isomorphism classes of data $(A, \iota, \lambda, \eta, \phi )$ as in § 4.2.1, except that the target of $\phi$ is $\hat {\mathbb {X}}^{b}_R:=\hat {\mathbb {X}}^{b}\times _{\breve {{\mathcal {O}}}_\wp }R$.
The group $\Delta$ defined in § 4.2 acts on $\overline {\mathfrak {Ig}}^b$, and we set $\mathfrak {Ig}^b:=\overline {\mathfrak {Ig}}^b/\Delta$.
5.1.4 Rapoport–Zink spaces
For every $\mathfrak {p} \in \Sigma _p$ we have the Rapoport–Zink space $\mathfrak {M}^{b_\mathfrak {p}}$ which is the formal scheme $\mathrm {Nilp}_{\breve {{\mathcal {O}}}_\wp } \rightarrow \mathrm {Sets}$ sending $R$ to the set of isomorphism classes of data $({\mathcal {G}}, \iota, \lambda, \rho )$, where:
(i) ${\mathcal {G}}$ is a $p$-divisible group over $R$;
(ii) $\iota : {\mathcal {O}}_{D, \mathfrak {p}}\rightarrow \mathrm {End}_R({\mathcal {G}})$ is an action of ${\mathcal {O}}_{D, \mathfrak {p}}:={\mathcal {O}}_D\otimes _{{\mathcal {O}}_F}{\mathcal {O}}_{F_\mathfrak {p}}$;
(iii) $\lambda$ is a polarisation compatible with the involution on ${\mathcal {O}}_{D, \mathfrak {p}}$ induced by $*$ and such that the Kottwitz condition is satisfied;
(iv) $\rho : {\mathcal {G}} \times _{R}R/p \rightarrow \mathbb {X}^{b_\mathfrak {p}}\times _{\bar {\mathbb {F}}_p}R/p$ is a quasi-isogeny commuting with the ${\mathcal {O}}_{D, \mathfrak {p}}$-action, and respecting polarisations up to a ${\mathbb {Q}}_p^\times$-factor.
Furthermore, we require $\lambda$ to be principal if $\mathfrak {p} \not \in T$. If $\mathfrak {p} \in T$, we ask the cokernel of the map induced by $\lambda$ on Lie algebras of the universal vector extensions of the relevant $p$-divisible groups to be locally free of rank two over $R \otimes _{{\mathbb {Z}}_p}\mathcal {O}_E/\mathfrak {p}\mathcal {O}_E$.
Two tuples $({\mathcal {G}}, \iota, \lambda, \rho )$ and $({\mathcal {G}}', \iota ', \lambda ', \rho ')$ are regarded as isomorphic if there exists an isomorphism ${\mathcal {G}} \rightarrow {\mathcal {G}}'$ commuting with $\iota$, $\iota '$, $\rho$ and $\rho '$, and respecting polarisations up to a ${\mathbb {Z}}_p^\times$-factor. Let $\mathfrak {M}^b:=\prod _{\mathfrak {p} \in \Sigma _p} \mathfrak {M}^{b_\mathfrak {p}}$.
5.1.5
We will now define a map $\alpha : \overline {\mathfrak {Ig}}^b \times _{\breve {{\mathcal {O}}}_\wp } \mathfrak {M}^b \rightarrow \mathfrak {X}^b$. We will denote the object to which some extra structure is attached by a subscript.
Fix $R \in \mathrm {Nilp}_{\breve {{\mathcal {O}}}_\wp }$ and take
Let ${\mathcal {G}}=\bigoplus _{\mathfrak {p} \in \Sigma _p}{\mathcal {G}}_\mathfrak {p}$ and let $\rho _ {\mathcal {G}}: {\mathcal {G}} \rightarrow \hat {\mathbb {X}}^b_R$ be the quasi-isogeny lifting $\bigoplus _{\mathfrak {p} \in \Sigma _p}\rho _{{\mathcal {G}}_\mathfrak {p}}$; we get a quasi-isogeny $\rho _{\mathcal {G}}^{-1}\circ \phi _A: A[p^\infty ]\rightarrow {\mathcal {G}}$ which commutes with the action of ${\mathcal {O}}_D$ and such that each component respects polarisations up to a ${\mathbb {Q}}_p^\times$-factor. We need to construct a point $(B, \iota _{B}, \lambda _{B}, \eta _{B}, \varphi _{B}) \in \mathfrak {X}^b(R)$.
Let $B$ be the unique abelian scheme in the $p$-isogeny class of $A$ such that $\rho _{\mathcal {G}}^{-1}\circ \phi _A$ induces an isomorphism $\gamma =(\gamma _\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}: B[p^\infty ] \buildrel \sim \over \to {\mathcal {G}}$. We endow $B$ with an action $\iota _B:{\mathcal {O}}_D \rightarrow \mathrm {End}_R(B)$ and with a level structure $\eta _{B}$ defined as in the proof of Lemma 4.2.2. To define the polarisation $\lambda _{B}$, look at the following diagram.
As in the proof of Lemma 4.2.2 we may rescale the quasi-isogeny $(q^\vee )^{-1}\circ \lambda _A\circ q^{-1}$ and get a polarisation $\lambda _B$ on $B$ such that $\gamma$ interchanges it with $\lambda _{\mathcal {G}}$ up to a ${\mathbb {Z}}_p^\times$-factor on each component. Finally, let $\bar {\gamma }$ be the reduction of $\gamma$ modulo $p$ and
Note that, by construction, the polarisation $\lambda _B$ is unchanged if ${\mathcal {G}}$ is replaced by a $p$-divisible group ${\mathcal {G}}'$ endowed with an isomorphism to ${\mathcal {G}}$ respecting the extra structures, the polarisation being respected up to a ${\mathbb {Z}}_p^\times$-factor on each component. Therefore, the resulting map $\alpha : \overline {\mathfrak {Ig}}^b \times _{\breve {{\mathcal {O}}}_\wp } \mathfrak {M}^b \rightarrow \mathfrak {X}^b$ is well-defined.
Lemma 5.1.6 The map $\alpha : \overline {\mathfrak {Ig}}^b \times _{\breve {{\mathcal {O}}}_\wp } \mathfrak {M}^b \rightarrow \mathfrak {X}^b$ is an isomorphism.
Proof. We will construct an inverse $\beta : \mathfrak {X}^b \rightarrow \overline {\mathfrak {Ig}}^b \times _{\breve {{\mathcal {O}}}_\wp } \mathfrak {M}^b$ of the map $\alpha$. Take $(B, \iota _{B}, \lambda _{B}, \eta _{B}, \varphi _{B}) \in \mathfrak {X}^b(R)$ and let ${\mathcal {G}}:=B[p^\infty ]$, endowed with the additional structures coming from $B$, and with the trivialisation $\rho _{\mathcal {G}}:=\varphi _B$. This gives an $R$-point of $\mathfrak {M}^b$. Finally, define $(A, \iota _A, \lambda _A, \eta _A, \phi _A)$ as follows: the abelian scheme $A$ is the unique one in the $p$-isogeny class of $B$ such that the lift of $\varphi _{B}$ induces an isomorphism $\phi _A: A[p^\infty ] \rightarrow \hat {\mathbb {X}}^b_R$, and the additional structures are obtained from those on $B$ as in the discussion before the statement of the lemma.
With the notation introduced in the construction of the map $\alpha$, the composite $\beta \circ \alpha$ sends
to
The map $\gamma$ gives an isomorphism, respecting polarisations up to ${\mathbb {Z}}_p^\times$ on each factor, between $(B[p^\infty ], \iota _B[p^\infty ], \lambda _B[p^\infty ], \bigoplus _{\mathfrak {p} \in \Sigma _p}\rho _{{\mathcal {G}}_\mathfrak {p}} \circ \bar {\gamma })$ and $({\mathcal {G}}, \iota _{{\mathcal {G}}}, \lambda _{{\mathcal {G}}}, \bigoplus _{\mathfrak {p} \in \Sigma _p}\rho _{{\mathcal {G}}_\mathfrak {p}})$, hence $\beta \circ \alpha$ is the identity map. Similarly one checks that $\alpha \circ \beta$ is the identity.
5.2 The product formula at infinite level and the Hodge–Tate period map
We now wish to establish an analogue in our situation of [Reference Caraiani and ScholzeCS17, Lemma 4.3.20].
5.2.1 Generic fibres of formal schemes
We will need to work with the adic generic fibres of the formal schemes introduced in the previous section. Recall that to a formal scheme $\mathfrak {M}$ over $\breve {{\mathcal {O}}}_\wp$ (locally admitting a finitely generated ideal of definition) one can attach an adic space $\mathfrak {M}^{ad}$ as in [Reference Scholze and WeinsteinSW13, Proposition 2.2.1] over $\mathrm {Spa}(\breve {{\mathcal {O}}}_\wp, \breve {{\mathcal {O}}}_\wp )$; one can then take the adic generic fibre
where $\breve {E}_\wp$ is the fraction field of $\breve {{\mathcal {O}}}_\wp$. With this notation, the product formula in Lemma 5.1.6 becomes, on the generic fibre:
The functors of points on complete affinoid $(\breve {E}_\wp, \breve {{\mathcal {O}}}_\wp )$-algebras of the adic spaces in the previous formula can be described using [Reference Scholze and WeinsteinSW13, Proposition 2.2.2]. It is easier, and sufficient for our purposes, to give such a description restricted to the category $\mathrm {Perf}_{\breve {E}_\wp }$ of perfectoid Huber pairs $(R, R^+)$ over $(\breve {E}_\wp, \breve {{\mathcal {O}}}_\wp )$. For example, the functor of points of $\mathcal {X}^b$ is the sheafification in the analytic topology of the functor
In other words, up to sheafification, an $(R, R^+)$-point of $\mathcal {X}^b$ is a compatible collection of data $(A_n, \iota _n, \lambda _n, \eta _n, \varphi _n)$ over $R^+/p^n$ as defined in § 5.1. Note that giving a compatible sequence of quasi-isogenies $\varphi _n$ just amounts to giving $\varphi _1$; on the other hand, we may see the compatible sequence $(A_n, \iota _n, \lambda _n, \eta _n)$ as a formal scheme with extra structure over $\operatorname {Spf} R^+$, which as above can be regarded as an adic space; we will denote it by $(\mathcal {A}, \iota, \lambda, \eta )$. Hence, the compatible sequence of data $(A_n, \iota _n, \lambda _n, \eta _n, \varphi _n)$ uniquely corresponds to a datum of the form $(\mathcal {A}, \iota, \lambda, \eta, \varphi )$.
A similar description can be given of the functor of points of the other objects appearing in (5.2.1.1), as well as of the good reduction locus $\mathcal {Y}_{U}(H)^\circ$ inside the analytification $\mathcal {Y}_{U}(H)$ of the space $Y_{U}(H)_{E_\wp }$; the space $\mathcal {Y}_{U}(H)^\circ$ is defined as the generic fibre of the completion along the special fibre of $Y_{U, {\mathcal {O}}_\wp }(H)$. In particular, [Reference Scholze and WeinsteinSW13, Lemma 2.2.2] applies and yields a description of the functor of points of $\mathcal {Y}_{U}(H)^\circ$ similar to that discussed above for $\mathcal {X}^b$. Note that the inclusion $\mathcal {Y}_{U}(H)^\circ \subset \mathcal {Y}_{U}(H)$ is an equality if $T$ is non-empty, but it is strict if $T$ is empty.
We will now introduce versions with infinite level at $p$ of the spaces considered so far.
5.2.2 The space $\mathcal {M}^b_{\infty }$
We will first define the Rapoport–Zink space at infinite level $\mathcal {M}^b_{\infty }:=\prod _{\mathfrak {p} \in \Sigma _p}\mathcal {M}^{b_\mathfrak {p}}_{\infty }$. Each $\mathcal {M}^{b_\mathfrak {p}}_{\infty }$ is a pro-étale cover of the generic fibre $\mathcal {M}^{b_\mathfrak {p}}$ of the adic space attached to the formal scheme $\mathfrak {M}^{b_\mathfrak {p}}$.
Fix $\mathfrak {p} \in \Sigma _p$; as recalled above, the functor of points $\mathrm {Perf}_{\breve {E}_\wp } \rightarrow \mathrm {Sets}$ of $\mathcal {M}^{b_\mathfrak {p}}$ is the sheafification of the functor sending $(R, R^+)$ to $\varprojlim _n \mathfrak {M}^{b_\mathfrak {p}}(R^+/p^n)$. Giving such a compatible system of $(R^+/p^n)$-points amounts to giving a compatible collection of $p$-divisible groups with extra structure $(\mathcal {G}_n, \iota _n, \lambda _n)$ as in § 5.1.4 and a quasi-isogeny (respecting extra structures) $\rho : \mathcal {G}_1 \rightarrow \mathbb {X}^{b_\mathfrak {p}} \times _{\bar {\mathbb {F}}_p} R^+/p$. Now, by [Reference MessingMes72, Lemma (4.16)], giving a compatible sequence of $p$-divisible groups with extra-structure $(\mathcal {G}_n, \iota _n, \lambda _n)$ is equivalent to giving a $p$-divisible group with extra structure $(\mathcal {G}, \iota, \lambda )$ over $R^+$. For every $n \geq 1$, the Tate module functor $T(\mathcal {G}_n)$ from $R^+/p^n$-algebras to sets sending $S$ to $\varprojlim _{k}\mathcal {G}_n[p^k](S)$ is represented by an affine scheme, flat over $\operatorname {Spec}(R^+/p^n)$, by [Reference Scholze and WeinsteinSW13, Proposition 3.3.1]. Taking the limit over $n$ and passing to the adic generic fibre we obtain an adic space which we denote by $\mathcal {T}(\mathcal {G})$.
The space $\mathcal {M}^{b_\mathfrak {p}}_{\infty }$ parametrises trivialisations of the local system on $\mathcal {M}^{b_\mathfrak {p}}$ given by $\mathcal {T}(\mathcal {G})$. More precisely, let $\Lambda _\mathfrak {p}=\Big (\begin{smallmatrix} \mathcal {O}_{E_\mathfrak {p}} & \mathcal {O}_{E_\mathfrak {p}}\\ \mathcal {O}_{E_\mathfrak {p}} & \mathcal {O}_{E_\mathfrak {p}} \end{smallmatrix}\Big )$ if $\mathfrak {p} \in \Sigma _p \smallsetminus T$ and $\Lambda _\mathfrak {p}=\Big (\begin{smallmatrix} \mathfrak {p}\mathcal {O}_{E_\mathfrak {p}} & \mathcal {O}_{E_\mathfrak {p}}\\ \mathfrak {p}\mathcal {O}_{E_\mathfrak {p}} & \mathcal {O}_{E_\mathfrak {p}} \end{smallmatrix}\Big )$ if $\mathfrak {p} \in T$ (as in [Reference Tian and XiaoTX16, p. 2154]). Following [Reference Scholze and WeinsteinSW13, Definition 6.5.3], we define
as the sheafification of the functor sending $(R, R^+)$ to the set of isomorphism classes of data $(\mathcal {G}, \iota, \lambda, \rho, \alpha )$, where $(\mathcal {G}, \iota, \lambda, \rho )$ is a datum as above, and
is an ${\mathcal {O}}_{D, \mathfrak {p}}$-linear map. We require that there is a compatible choice of $p$-power roots of unity in $R^+$, yielding a map $\varepsilon : {\mathbb {Z}}_p \rightarrow \mathcal {T}(\mu _{p^\infty })(R, R^+)$, such that the pairing $\mathrm {Tr} (\psi ):\Lambda _\mathfrak {p} \times \Lambda _\mathfrak {p} \rightarrow {\mathbb {Z}}_p$ and the pairing $\mathcal {T}\mathcal {G}(R, R^+) \times \mathcal {T}\mathcal {G}(R, R^+) \rightarrow \mathcal {T}(\mu _{p^\infty })(R, R^+)$ induced by the polarisation are identified via the maps $\alpha$ and $\varepsilon$. Furthermore, we ask that for every map $x: \mathrm {Spa}(K, K^+) \rightarrow \mathrm {Spa}(R, R^+)$ with $K$ a perfectoid field, the induced map $\Lambda _\mathfrak {p} \rightarrow \mathcal {T}(\mathcal {G})(K, K^+)$ is an isomorphism.
5.2.3 The space $\mathcal {Y}_{U^p}(H)^{\circ }$
Let $\mathcal {Y}_{U^p}(H)/\breve {E}_\wp$ be the inverse limit of the diamonds attached to the analytifications of the varieties $Y_{U^pU_p}(H)_{\breve {E}_\wp }$, as the compact open subgroup $U_p\subset H({\mathbb {Q}}_p)$ varies (cf. Remark 3.3.2). We denote by $\mathcal {Y}_{U^p}(H)^\circ \subset \mathcal {Y}_{U^p}(H)$ the preimage of $\mathcal {Y}_{U}(H)^\circ _{\breve {E}_\wp }$ via the natural projection map. The same argument used in § 5.2.1 shows that $\mathcal {Y}_{U}(H)^\circ : \mathrm {Perf}_{\breve {E}_\mathfrak {p}} \rightarrow \mathrm {Sets}$ is the sheafification of the functor sending $(R, R^+)$ to the set of isomorphism classes of data $(\mathcal {A}, \iota, \lambda, \eta )/\operatorname {Spf} R^+$. On the other hand $\mathcal {Y}_{U^p}(H)$ is the inverse limit of the analytifications of schemes over $Y_{U}(H)_{\breve {E}_\wp }$ relatively representing trivialisations (respecting extra structure) of the $p^n$-torsion in the universal abelian scheme. It follows that $\mathcal {Y}_{U^p}(H)^\circ : \mathrm {Perf}_{\breve {E}_\wp } \rightarrow \mathrm {Sets}$ is the sheafification of the functor sending $(R, R^+)$ to the set of isomorphism classes of data $(\mathcal {A}, \iota, \lambda, \eta, \alpha )$, where $\alpha : \Lambda _p=\bigoplus _{\mathfrak {p} \in \Sigma _p}\Lambda _\mathfrak {p} \rightarrow \mathcal {T}(\mathcal {A}[p^\infty ])(R, R^+)$ is a trivialisation in the sense of § 5.2.2.
There is a continuous specialisation map $\mathcal {Y}_{U}(H)^\circ \rightarrow Y_{U}(H)\times _{\breve {{\mathcal {O}}}_\wp } \bar {{\mathbb {F}}}_p$; define $\mathcal {Y}_{U^p}(H)^{b} \subset \mathcal {Y}_{U^p}(H)^{\circ }$ to be the preimage of the Newton stratum in $Y_{U}(H)\times _{\breve {{\mathcal {O}}}_\wp } \bar {{\mathbb {F}}}_p$ corresponding to $b \in B(H_{{\mathbb {Q}}_p}, \mu )$ via the composition of the specialisation map and the projection map $\mathcal {Y}_{U^p}(H)^{\circ } \rightarrow \mathcal {Y}_{U}(H)^\circ _{\breve {E}_\wp }$. Hence, $\mathcal {Y}_{U^p}(H)^{b}$ is a locally closed subspace of (the topological space underlying) $\mathcal {Y}_{U^p}(H)^{\circ }$.
5.2.4 The space $\mathcal {X}^b_{\infty }$
Finally, we will need the infinite level version of the space $\mathcal {X}^b$. This is the sheafification of the functor sending $(R, R^+) \in \mathrm {Perf}_{\breve {E}_\wp }$ to the set of isomorphism classes of data $(\mathcal {A}, \iota, \lambda, \eta, \varphi, \alpha )$ where $(\mathcal {A}, \iota, \lambda, \eta, \varphi )$ is as in § 5.2.1, and $\alpha$ is a trivialisation of $\mathcal {T}(\mathcal {A}[p^\infty ])(R, R^+)$ in the sense defined above.
5.2.5
From now on, unless otherwise stated we will regard all our objects as diamonds over $\mathrm {Spd}(\breve {E}_\wp, \breve {{\mathcal {O}}}_\wp )$; in particular, to define maps between them it suffices to give natural transformations between the functors on $\mathrm {Perf}_{\breve {E}_\wp }$ described above. We have a map $\mathcal {X}^b_{\infty }\rightarrow \mathcal {M}^b_\infty$, obtained sending an abelian scheme with extra structure to the associated $p$-divisible group with extra structure. This fits into the following cartesian diagram.
Indeed, the above diagram is clearly cartesian on the non-sheafified functors of points, and sheafification commutes with finite limits. It follows that $\mathcal {X}^b_{\infty }$ is representable by an adic space. Furthermore, the product formula (5.2.1.1) is still true at infinite level, as
The diamond $\mathcal {X}^b_\infty$ maps to $\mathcal {Y}_{U^p}(H)^{\circ }$ forgetting the quasi-isogeny $\varphi$; the underlying map of topological spaces factors through a map
We warn the reader that the subset $\mathcal {Y}_{U^p}(H)^{b}\subset \mathcal {Y}_{U^p}(H)$ is not necessarily generalising, hence it may not be the underlying topological space of a subdiamond of $\mathcal {Y}_{U^p}(H)$. For $(R, R^+) \in \mathrm {Perf}_{\breve {E}_\wp }$, we will denote by $\mathcal {Y}_{U^p}(H)^{b}(R, R^+)$ the set of maps from $\mathrm {Spa}(R, R^+)$ to $\mathcal {Y}_{U^p}(H)$ whose image is contained in $\mathcal {Y}_{U^p}(H)^{b}$.
Finally, we have global and local Hodge–Tate period maps
We can now state and prove an analogue of [Reference Caraiani and ScholzeCS17, Lemma 4.3.20].
Proposition 5.2.6 The following diagram (of functors on $\mathrm {Perf}_{\breve {E}_\wp }$) is cartesian.
Proof. As sheafification commutes with finite limits, it is enough to prove the statement at the level of non-sheafified functors of points.
(i) First we show that the diagram commutes. It is enough to prove this for $\mathrm {Spa}(K, K^+)$-points with $K$ a complete algebraically closed field and $K^+ \subset K$ an open bounded valuation subring, and replacing $\mathcal {Y}_{U^p}(H)^{b}$ with $\mathcal {Y}_{U^p}(H)$. Because $\mathscr {F}\ell _{H_{{\mathbb {Q}}_p}, \mu^{-1}}$ is separated (it is even proper), we are reduced to prove commutativity on $\mathrm {Spa}(K, {\mathcal {O}}_K)$-points. In this case, it follows from the compatibility of the Hodge–Tate filtration for an abelian variety and the associated $p$-divisible group [Reference ScholzeSch13, Proposition 4.15].
(ii) It remains to prove that the diagram is cartesian. Let $(R, R^+) \in \mathrm {Perf}_{\breve {E}_\wp }$ and take two points
mapping to the same $(R, R^+)$-point of the flag variety. The map $\alpha _{\mathcal {G}} \circ \alpha _A^{-1}: \mathcal {T}_p(\mathcal {A})(R, R^+)\rightarrow \mathcal {T}_p(\mathcal {G})(R, R^+)$ becomes an isomorphism when pulled back to any geometric rank one point $\mathrm {Spa}(K, {\mathcal {O}}_K)$, and it is induced by an isomorphism $\phi : \mathcal {A}[p^\infty ]_R\buildrel \sim \over \to \mathcal {G}_R$ respecting the extra structures. Furthermore, as $x$ and $y$ map to the same point in the flag variety, the map $\alpha _{\mathcal {G}} \circ \alpha _A^{-1}$ respects the Hodge–Tate filtrations (on Tate modules tensored by $K$). Finally, since the image of $y$ is contained in $\mathcal {Y}_{U^p}(H)^{b}$, the Newton polygon of $\mathcal {A}[p^\infty ]\times _{R^+}R^+/p$ is constant. Hence, by [Reference Scholze and WeinsteinSW13, Theorem B] and [Reference Caraiani and ScholzeCS17, Lemma 4.2.15], the isomorphism $\phi$ extends to an isomorphism, abusively denoted by the same symbol, $\phi : \mathcal {A}[p^\infty ]\buildrel \sim \over \to \mathcal {G}$. We get a (unique) $(R, R^+)$-point $(\mathcal {A}, \iota _\mathcal {A}, \lambda _\mathcal {A}, \eta _\mathcal {A}, \alpha _\mathcal {A}, \rho _{\mathcal {G}} \circ \phi )$ of $\mathcal {X}^b_{\infty }$ mapping to $x$ and $y$.
5.2.7
We have a natural map from $\mathcal {Y}_{U^p}(H)=\varprojlim _{U_p}\mathcal {Y}_{U^pU_p}$ to the inverse limit $\mathcal {S}h_{U^p}(H)$ of the analytifications $\mathcal {S}h_{U^pU_p}(H)$ of the Shimura varieties with level $U^pU_p$; this map is a torsor for the group $\Delta =\varprojlim _k \Delta _k$ defined in § 4.2. We let $\mathcal {S}h_{U^pU_{p}}(H)^\circ =\mathcal {Y}_{U^pU_p}^\circ /\Delta$ and $\mathcal {S}h_{U^p}(H)^\circ =\mathcal {Y}^\circ _{U^p}(H)/\Delta$, so that $\mathcal {S}h_{U^p}(H)^\circ /U_p\simeq \mathcal {S}h_{U^pU_p}(H)^\circ$. Similarly, we set $\mathcal {S}h_{U^p}(H)^b=\mathcal {Y}_{U^p}(H)^b/\Delta$ for $b \in B(H_{{\mathbb {Q}}_p}, \mu )$.
5.3 Fibres of the Hodge–Tate period map
Recall that we have fixed a subset $T \subset \Sigma _p$; we have a Hodge–Tate period map
induced by the map (abusively denoted with the same symbol) $\pi _{\mathrm {HT}}^\circ : \mathcal {Y}_{U^p}(H)^{\circ } \rightarrow \mathscr {F}\ell _{H_{{\mathbb {Q}}_p}, \mu^{-1} }$ introduced above, which is equivariant with respect to the $\Delta$-action (trivial on the target). Take an element $b \in B(H_{{\mathbb {Q}}_\mathfrak {p}}, \mu )$, and fix a $p$-divisible group $\mathbb {X}^b$ (with extra structure) corresponding to it.
Proposition 5.3.1 For every geometric point $\tilde {x}$ of $\mathscr {F}\ell ^b_{H_{{\mathbb {Q}}_p}, \mu^{-1} }$ and every $i \geq 0$ there is a Hecke-equivariant isomorphism
Proof. This follows from Proposition 5.2.6 with the same argument as in [Reference Caraiani and ScholzeCS17, § 4.4]. More precisely, we may assume that $\tilde {x}= \mathrm {Spa}(C, \mathcal {O}_C)$ is a rank one point; any rank one point in the preimage of $\tilde {x}$ in $\mathcal {Y}_{U^p}(H)^{\circ }$ is contained in $\mathcal {Y}_{U^p}(H)^{b}$. The cartesian diagram in Proposition 5.2.6, [Reference Caraiani and ScholzeCS17, Lemma 4.2.18] and the product formula for $\mathcal {X}^{b}_\infty$ (5.2.5.1) imply that the fibre of $\pi _{\mathrm {HT}}^\circ : \mathcal {Y}_{U^p}(H)^{b} \rightarrow \mathscr {F}\ell ^b_{H_{{\mathbb {Q}}_p}, \mu^{-1} }$ at $\tilde {x}$ is isomorphic to $\overline {\mathcal {I}g^b}_{(C, \mathcal {O}_C)}$, hence the fibre of $\pi _{\mathrm {HT}}^\circ : \mathcal {S}h_{U^p}(H)^{b} \rightarrow \mathscr {F}\ell ^b_{H_{{\mathbb {Q}}_p}, \mu^{-1} }$ is isomorphic to $\mathcal {I}g^b_{(C, \mathcal {O}_C)}$. The result now follows as in [Reference Caraiani and ScholzeCS17, pp. 728 and 729].
6. The structure of the $\mu$-ordinary stratum at infinite level
In this section, we show that the $\mu$-ordinary locus at infinite level is parabolically induced from the corresponding perfectoid Igusa variety.
6.1 Setup
Fix a prime $p$ and a subset $T \subsetneq \Sigma _p$ as in the previous section; we will mostly omit $T$ from our notations: for example, we denote $H_T$ by $H$. As explained in § 4.1 we have $B(H_{{\mathbb {Q}}_p}, \mu )=\prod _{\mathfrak {p} \in \Sigma _p} B(H_{\mathfrak {p}}, \mu _{\mathfrak {p}})$, where $B(H_{\mathfrak {p}}, \mu _{\mathfrak {p}})$ is a singleton if $\mathfrak {p} \in T$ and has two elements, the basic one and the $\mu _\mathfrak {p}$-ordinary one, if $\mathfrak {p} \in \Sigma _p \smallsetminus T$. Consider the $\mu$-ordinary element $b^{\mathrm {ord}}=(b_\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}$ where $b_\mathfrak {p}$ is the non-basic element for every $\mathfrak {p} \in \Sigma _p \smallsetminus T$. Our aim is to study the structure of the stratum $\mathcal {S}h_{U^p}(H)^{b^\mathrm {ord}}$, proving that it is parabolically induced from the corresponding perfectoid Igusa variety. This rests on the product formula
we proved in the previous section and on the fact that the relevant Rapoport–Zink spaces are parabolically induced.
6.1.1 The group $\mathcal {J}^{b^\mathrm {ord}}$
Let $\mathcal {J}^{b^\mathrm {ord}}=\prod _{\mathfrak {p} \in \Sigma _p}\mathcal {J}^{b_\mathfrak {p}}$ be the group of self-quasi-isogenies (respecting extra structure) of $\mathbb {X}^{b^\mathrm {ord}}$, seen as a functor $\mathrm {Perf}_{\breve {E}_\wp } \to \mathrm {Sets}$ sending $(R, R^+)$ to the set of self-quasi-isogenies of $\mathbb {X}^{b^\mathrm {ord}}\times _{\bar {{\mathbb {F}}}_p}R^+/p$. If $\mathfrak {p} \in T$, then $\mathcal {J}^{b_\mathfrak {p}}$ is just the constant group diamond attached to $H_\mathfrak {p}({\mathbb {Q}}_p)$, which will be denoted by $\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$. If $\mathfrak {p} \in \Sigma _p \smallsetminus T$ then we can write $\mathcal {J}^{b_\mathfrak {p}}=\underline {L_{\mathfrak {p}}({\mathbb {Q}}_p)} \ltimes \mathcal {J}_\mathfrak {p}^{U}$ where $L_{\mathfrak {p}}\subset H_\mathfrak {p}$ is a Levi and $\mathcal {J}_\mathfrak {p}^{U}$ is a (positive-dimensional) group diamond (cf. [Reference Caraiani and ScholzeCS17, Proposition 4.2.11]). On the other hand, we can attach to $\mathbb {X}^{b^\mathrm {ord}}$ an $H_{{\mathbb {Q}}_p}$-bundle $\mathcal {E}^{b^\mathrm {ord}}_{(R, R^+)}$ on the Fargues–Fontaine curve $X_{(R^\flat, R^{\flat,+})}$ for each $(R, R^+) \in \mathrm {Perf}_{\breve {E}_\wp }$, and look at the corresponding automorphism group functor $\mathrm {Aut}(\mathcal {E}^{b^\mathrm {ord}}): \mathrm {Perf}_{\breve {E}_\wp } \to \mathrm {Sets}$.
We claim that $\mathrm {Aut}(\mathcal {E}^{b^\mathrm {ord}})\simeq \mathcal {J}^{b^\mathrm {ord}}$. Indeed, for $\mathfrak {p} \in \Sigma _p \smallsetminus T$, [Reference Fargues and ScholzeFS21, Proposition III.5.1] describes $\mathrm {Aut}(\mathcal {E}^{b_\mathfrak {p}})$ in terms of $\underline {L_{\mathfrak {p}}({\mathbb {Q}}_p)}$ and of Banach–Colmez spaces. On the other hand, the computation in the proof of [Reference Caraiani and ScholzeCS17, Proposition 4.2.11] gives a similar description of $\mathcal {J}^{b_\mathfrak {p}}$, with the universal cover of suitable $p$-divisible groups in place of Banach–Colmez spaces. The desired isomorphism follows from the identification between these two objects, cf. [Reference Scholze and WeinsteinSW20, § 15.2].
6.1.2
The description of the Igusa variety in Lemma 4.2.2 implies that $\mathcal {J}^{b^\mathrm {ord}}$ acts on the left on $\overline {\mathcal {I}g}^{b^{\mathrm {ord}}}$, changing the trivialisation $\rho$. For the same reason, $\mathcal {J}^{b^\mathrm {ord}}$ acts on the left on $\mathcal {M}_\infty ^{b^{\mathrm {ord}}}$ and $\mathcal {X}_\infty ^{b^\mathrm {ord}}$. The stratum $\mathcal {Y}_{U^p}(H)^{b^\mathrm {ord}}\subset \mathcal {Y}_{U^p}(H)^\circ$ is open and contained in the preimage via $\pi _{HT}^\circ$ of the $\mu$-ordinary stratum in the flag variety. As the latter is a diamond, the same is true for $\mathcal {Y}_{U^p}(H)^{b^\mathrm {ord}}$. The map $\mathcal {X}^{b^\mathrm {ord}}_{\infty } \rightarrow \mathcal {Y}_{U^p}(H)^{b^\mathrm {ord}}$ is invariant with respect to the action of $\mathcal {J}^{b^\mathrm {ord}}$ on the source.
Lemma 6.1.3
(i) The map $\mathcal {J}^{b^\mathrm {ord}} \backslash \mathcal {X}^{b^\mathrm {ord}}_{\infty } \rightarrow \mathcal {Y}_{U^p}(H)^{b^\mathrm {ord}}$ is an isomorphism.
(ii) The induced map $\mathcal {J}^{b^\mathrm {ord}} \backslash (\mathcal {I}g^{b^{\mathrm {ord}}} \times \mathcal {M}_\infty ^{b^{\mathrm {ord}}}) \rightarrow \mathcal {S}h_{U^p}(H)^{b^\mathrm {ord}}$ is an isomorphism.
Proof. The second point follows from the first and the product formula: indeed, as the map in (5.2.1.1) (as well as its counterpart at infinite level (5.2.5.1)) is $\mathcal {J}^{b^\mathrm {ord}}$-equivariant, we get an isomorphism
The above isomorphism is equivariant with respect to the $\Delta$-action on $\overline {\mathcal {I}g^{b^{\mathrm {ord}}}}$ and on $\mathcal {Y}_{U^p}(H)^{b^\mathrm {ord}}$; hence, quotienting by this action we obtain the desired isomorphism.
To prove the first point, we need to show that the map (of pro-étale sheaves) $\mathcal {X}^{b^\mathrm {ord}}_{\infty } \rightarrow \mathcal {Y}_{U^p}(H)^{b^\mathrm {ord}}$ is surjective. Let $(R, R^+) \in \mathrm {Perf}_{\breve {E}_\wp }$ and let $\mathcal {G}/R^+$ be the $p$-divisible group with extra structure attached to an $(R, R^+)$-point of the target. Then, after base change to any geometric point of $\mathrm {Spa}(R, R^+)$, we have a quasi-isogeny respecting extra structures between $\mathcal {G}\times _{R^+}R^+/p$ and $\mathbb {X}^{b^\mathrm {ord}}\times _{\bar {\mathbb {F}}_p}R^+/p$. Therefore, the isocrystal attached to the $p$-divisible group with extra structure $\mathcal {G}\times _{R^+}R^+/p$ gives rise to an $H$-bundle $\mathcal {E}_{\mathcal {G}}$ on the Fargues–Fontaine curve $X_{(R^\flat, R^{\flat,+})}$ which is geometrically fibrewise isomorphic to the $H$-bundle $\mathcal {E}^{b^{\mathrm {ord}}}$ corresponding to $b^{\mathrm {ord}}$. By [Reference Fargues and ScholzeFS21, Proposition III.5.3], there is, pro-étale locally on $\mathrm {Spa}(R^\flat, R^{+, \flat })$, an isomorphism $\mathcal {E}_{\mathcal {G}}\simeq \mathcal {E}^{b^{\mathrm {ord}}}$, yielding, pro-étale locally, a quasi-isogeny respecting extra-structures between $\mathcal {G}\times _{R^+}R^+/p$ and $\mathbb {X}^{b^\mathrm {ord}}\times _{\bar {\mathbb {F}}_p}R^+/p$.
6.2 The structure of $\mu$-ordinary Rapoport–Zink spaces
6.2.1 Moduli spaces of shtukas
Given $\mathfrak {p} \in \Sigma _p$, we can attach to $(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ a diamond $Sht_\infty (H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ over $\mathrm {Spd}(\breve {E}_\wp, \breve {\mathcal {O}}_{\wp })$ parametrising $H_\mathfrak {p}$-shtukas with infinite level structure, as in [Reference Scholze and WeinsteinSW20, § 23]. More precisely, the functor $Sht_\infty (H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p}): \mathrm {Perf}_{\bar {{\mathbb {F}}}_p}\rightarrow \mathrm {Sets}$ sends $(R, R^+)$ to the set of isomorphism classes of data of the form $(S^\sharp, \mathcal {E}, \mathcal {E}', \phi, \rho, \rho _{\infty })$, where:
(i) $S^\sharp /\mathrm {Spa}(\breve {E}_\wp, \breve {\mathcal {O}}_\wp )$ is an untilt of $S:=\mathrm {Spa}(R, R^+)$;
(ii) $\mathcal {E}, \mathcal {E}'$ are $H_\mathfrak {p}$-bundles over the relative Fargues-Fontaine curve $X_S$;
(iii) $\phi$ is an isomorphism between $\mathcal {E}$ and $\mathcal {E}'$ outside $S^\sharp$, which is a modification of type $\mu _\mathfrak {p}$ at $S^\sharp$;
(iv) $\rho : \mathcal {E}' \rightarrow \mathcal {E}^{b_\mathfrak {p}}$ is an isomorphism, where $\mathcal {E}^{b_\mathfrak {p}}$ is the $H_\mathfrak {p}$-bundle on $X_S$ coming from (the isocrystal attached to) $\mathbb {X}^{b_\mathfrak {p}}$;
(v) $\rho _\infty : \mathcal {E}^1 \rightarrow \mathcal {E}$ is an isomorphism, where $\mathcal {E}^1$ is the trivial $H_\mathfrak {p}$-bundle on $X_S$.
By [Reference Scholze and WeinsteinSW20, Corollary 24.3.5], the diamond $Sht_\infty (H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ is isomorphic to $\mathcal {M}^{b_\mathfrak {p}}_\infty$.
We have a left (respectively, right) action of $\mathcal {J}^{b_\mathfrak {p}}=\mathcal {A}ut(\mathcal {E}^{b_\mathfrak {p}})$ (respectively, $\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}=\mathcal {A}ut(\mathcal {E}^1)$) on the space $Sht_\infty (H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$, changing the trivialisation $\rho$ (respectively, $\rho _\infty$). The former corresponds to the action of $\mathcal {J}^{b_\mathfrak {p}}$ on $\mathcal {M}^{b_\mathfrak {p}}_\infty$ recalled above.
6.2.2 The space $\mathcal {M}^{b_\mathfrak {p}}_\infty$ for $\mathfrak {p} \in T$
If $\mathfrak {p} \in T$, then the cocharacter $\mu _\mathfrak {p}$ is central, hence the flag variety $\mathscr {F}\ell _{H_{\mathfrak {p}}, \mu _\mathfrak {p}}$ is a point. By [Reference Scholze and WeinsteinSW20, Proposition 19.4.2] and [Reference Scholze and WeinsteinSW20, proof of Proposition 23.3.3] the diamond $\mathcal {M}^{b_\mathfrak {p}}_\infty$ is isomorphic to the diamond $\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$ attached to the locally profinite set $H_\mathfrak {p}({\mathbb {Q}}_p)$. Hence, the product $\mathcal {M}_{T, \infty }:=\prod _{\mathfrak {p} \in T} \mathcal {M}^{b_\mathfrak {p}}_\infty$ is isomorphic to $\prod _{\mathfrak {p} \in T}\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$.
6.2.3 The space $\mathcal {M}^{b_\mathfrak {p}}_\infty$ for $\mathfrak {p} \in \Sigma _p \smallsetminus T$
Now fix $\mathfrak {p} \in \Sigma _p \smallsetminus T$ and let $b_\mathfrak {p} \in B(H_\mathfrak {p}, \mu _\mathfrak {p})$ be the $\mu _\mathfrak {p}$-ordinary element. The structure of $Sht_\infty (H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ is studied in [Reference Gaisin and ImaiGI16] (generalising [Reference HansenHan21]), whose main result we now recall in the situation of interest to us: we warn the reader that our notation differs from that in [Reference Gaisin and ImaiGI16]. We have a forgetful map from $Sht_\infty (H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ to the Hecke stack $\mathrm {Hecke}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ which parametrises data $(S^\sharp, \mathcal {E}, \mathcal {E}', \phi )$ as above, such that $\mathcal {E}'$ (respectively, $\mathcal {E}$) is fibrewise isomorphic to $\mathcal {E}^{b_\mathfrak {p}}$ (respectively, $\mathcal {E}^1$). The Grassmannian $Gr(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ is the $\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$-torsor over $\mathrm {Hecke}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ parametrising trivialisations $\rho _\infty : \mathcal {E}^1 \rightarrow \mathcal {E}$. Consider the subfunctor $\mathcal {C}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})\subset Gr(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ obtained imposing the condition that $\rho _\infty$ and $\phi$ are compatible with the filtrations, in the sense of [Reference Gaisin and ImaiGI16, p. 9]. The right action of $\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$ on $Gr(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ induces a right action of a parabolic $\underline {P_\mathfrak {p}({\mathbb {Q}}_p)}\supset \underline {L_\mathfrak {p}({\mathbb {Q}}_p)}$ on the subspace $\mathcal {C}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})\subset Gr(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$. The natural map $\mathcal {C}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})\times \underline {H_\mathfrak {p}({\mathbb {Q}}_p)}\rightarrow Gr(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ is invariant with respect to the left action of $\underline {P_\mathfrak {p}({\mathbb {Q}}_p)}$ on the source given by the product of the inverse of the right action on $\mathcal {C}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ and the left action by multiplication on $\underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$. By [Reference Gaisin and ImaiGI16, Proposition 4.13] the induced map
is an isomorphism.
Now let us consider the moduli space of shtukas $Sht_{P_\mathfrak {p}}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ with ‘parabolic level structure’, defined as the fibre product as follows.
The isomorphism (6.2.3.1) yields an isomorphism
6.2.4 The structure of $Sht_{P_\mathfrak {p}}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$
The data $b_\mathfrak {p}, \mu _\mathfrak {p}$ are induced by analogous data for the Levi $L_\mathfrak {p}$, which we will abusively denote by the same symbol. In other words, our data are HN-reducible in the sense of [Reference Gaisin and ImaiGI16, Definition 4.5] (note that only one of the elements $b$, $b'$ considered in [Reference Gaisin and ImaiGI16, Definition 4.5] is non-trivial in our case). We can consider the corresponding moduli space of shtukas $Sht_\infty (L_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$; in fact, as $L_\mathfrak {p}$ is abelian, the same argument used above shows that $Sht_\infty (L_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$ is just the diamond attached to the locally profinite set $L_\mathfrak {p}({\mathbb {Q}}_p)$. Inducing bundles from $L_\mathfrak {p}$ to $H_\mathfrak {p}$ we obtain a map $Sht_\infty (L_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})\rightarrow Sht_{P_\mathfrak {p}}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$. Finally, the group object $\mathcal {J}_\mathfrak {p}^{U}$ acts on the left on $Sht_{P_\mathfrak {p}}(H_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$, hence we obtain a map
By [Reference Gaisin and ImaiGI16, Proposition 4.21] the above map is an isomorphism. Joining this with (6.2.3.2) we obtain the following isomorphism, where fibre products are taken over $\mathrm {Spd}(\breve {E}_\wp, \breve {\mathcal {O}}_{\wp })$, which is omitted from the notation:
Define $Sht_\infty (L^T, b^T, \mu ^T):=\prod _{\mathfrak {p} \in \Sigma _p \smallsetminus T}Sht_\infty (L_\mathfrak {p}, b_\mathfrak {p}, \mu _\mathfrak {p})$; similarly, we denote by $P^{T}({\mathbb {Q}}_p), \mathcal {J}^{U, T}$ and $H^T({\mathbb {Q}}_p)$ the product of the objects $P_\mathfrak {p}({\mathbb {Q}}_p), \mathcal {J}^U_\mathfrak {p}$ and $H_\mathfrak {p}({\mathbb {Q}}_p)$ for $\mathfrak {p} \in \Sigma _p \smallsetminus T$. With this notation, the space $\mathcal {M}^{b_\mathrm {ord}}_\infty$ can be written as
6.3 The almost product formula on the $\mu$-ordinary stratum
6.3.1
We can now join Lemma 6.1.3 and the above description of $\mathcal {M}^{b_\mathrm {ord}}_\infty$. Let $\mathcal {J}^T:=\prod _{\mathfrak {p} \in \Sigma _p \smallsetminus T}\mathcal {J}^{b_\mathfrak {p}}$. Since for $\mathfrak {p} \in T$ we have $\mathcal {M}^{b_\mathfrak {p}}_\infty \simeq \mathcal {J}^{b_\mathfrak {p}}\simeq \underline {H_\mathfrak {p}({\mathbb {Q}}_p)}$ we obtain the following description of the ordinary stratum $\mathcal {S}h_{U^p}(H)^{b^\mathrm {ord}}$:
We will now show that the space on the right-hand side is isomorphic to
where $\underline {P^{T}({\mathbb {Q}}_p)}$ acts on the left on $\mathcal {I}g^{b^\mathrm {ord}}$ via the natural inclusion in $\mathcal {J}^T$ and on $\underline {H^T({\mathbb {Q}}_p)}$ via left multiplication.
Sending (the equivalence class of) a point $(i, g)$ to (the equivalence class of) $(i, ((1, 1), g))$ gives a well-defined map from the space in (6.3.1.1) to $\mathcal {S}h_{U^p}(H)^{b^\mathrm {ord}}$. This map is surjective because $\mathcal {J}^{T}$ acts transitively on $Sht_\infty (L^T, b^T, \mu ^T)\times \mathcal {J}^{U, T}$; injectivity can be checked directly. Hence, we obtain an isomorphism
which is equivariant with respect to the right action of $\underline {H({\mathbb {Q}}_p)}$ on the source and the target (here $\underline {H^T({\mathbb {Q}}_p)}$ acts on the target via right multiplication on itself).
Notation 6.3.2 In the next theorem and its proof we will use the following notation. We set $P({\mathbb {Q}}_p):=\prod _{\mathfrak {p} \in T}H_\mathfrak {p}({\mathbb {Q}}_p)\times \prod _{\mathfrak {p} \in \Sigma _p \smallsetminus T}P_\mathfrak {p}({\mathbb {Q}}_p) \subset H({\mathbb {Q}}_p)$; similarly, let $P({\mathbb {Z}}_p):=\prod _{\mathfrak {p} \in T}H_\mathfrak {p}({\mathbb {Z}}_p)\times \prod _{\mathfrak {p} \in \Sigma _p \smallsetminus T}P_\mathfrak {p}({\mathbb {Z}}_p) \subset H({\mathbb {Z}}_p)$. We will denote by $\mathrm {Ind}$ smooth induction.
Theorem 6.3.3
(i) There is an $\underline {H({\mathbb {Q}}_p)}$-equivariant isomorphism
\[ \mathcal{S}h_{U^p}(H)^{b^\mathrm{ord}}\simeq \underline{P^T({\mathbb{Q}}_p)} \backslash \big(\mathcal{I}g^{b^\mathrm{ord}}\times \underline{H^T({\mathbb{Q}}_p)} \big). \](ii) Let us turn the left action of $\underline {P({\mathbb {Q}}_p)}$ on $\mathcal {I}g^{b^\mathrm {ord}}$ into a right action taking the inverse. Then the cohomology of $\mathcal {I}g^{b^\mathrm {ord}}$ (respectively, $\mathcal {S}h_{U^p}(H)^{b^\mathrm {ord}}$) carries a left action of $P({\mathbb {Q}}_p)$ (respectively, $H({\mathbb {Q}}_p)$). For each $i \geq 0$, we have an isomorphism of smooth $H({\mathbb {Q}}_p)$-representations
\[ H^i(\mathcal{S}h_{U^p}(H)^{b^\mathrm{ord}}, {\mathbb{F}}_{\ell})\simeq \mathrm{Ind}_{P({\mathbb{Q}}_p)}^{H({\mathbb{Q}}_p)}\big( H^i(\mathcal{I}g^{b^\mathrm{ord}}, {\mathbb{F}}_{\ell})\big). \]
Proof. The first point was established before the statement of the theorem; let us prove the second point. Fix $i \geq 0$ and let $I:=\mathcal {I}g^{b^\mathrm {ord}}$ and $V:=H^i(I, {\mathbb {F}}_\ell )$. The subgroup $P({\mathbb {Z}}_p)\subset P({\mathbb {Q}}_p)$ acts freely on $\overline {\mathcal {I}g^{b^\mathrm {ord}}}$. On the other hand, for $u \in \mathcal {O}_{E}^{\times }\cap U^p$, the action of $N_{E/F}(u)$ (changing polarisation) on $\overline {\mathcal {I}g^{b^\mathrm {ord}}}$ agrees with the action of $u^{-1} \in P({\mathbb {Z}}_p)$. The induced action of $P({\mathbb {Z}}_p)$ on $I$ hence factors through a free action of $P({\mathbb {Z}}_p)/C$, where $C:=\varprojlim _k(\mathcal {O}_E^{\times }\cap U^p/\{u \in \mathcal {O}_E^{\times }\cap U^p \mid u \equiv 1 \pmod {p^k}\})$.
The action of $P({\mathbb {Q}}_p)$ on $I$ induces a map $\rho : P({\mathbb {Q}}_p) \rightarrow \mathrm {Aut}(V)$. The map $\iota : I \rightarrow \underline {P({\mathbb {Q}}_p)}\backslash I \times \underline {H({\mathbb {Q}}_p)}$ sending $x$ to $(x, 1)$ is equivariant with respect to the right $\underline {P({\mathbb {Q}}_p)}$-action on source and target, hence it induces a $P({\mathbb {Q}}_p)$-equivariant map
We therefore have an $H({\mathbb {Q}}_p)$-equivariant map
induced by $\iota ^*$ via Frobenius reciprocity, which sends a cohomology class $c$ to the function $H({\mathbb {Q}}_p)\rightarrow V$ sending $h$ to $\iota ^*\circ h^{*}(c)$. For every compact open subgroup $K \subset H({\mathbb {Q}}_p)$ we have the space $I_{K}:=\underline {P({\mathbb {Q}}_p)}\backslash (I \times \underline {H({\mathbb {Q}}_p)}/\underline {K})$ and the natural map $q_K: \underline {P({\mathbb {Q}}_p)}\backslash (I \times \underline {H({\mathbb {Q}}_p)}) \rightarrow I_K$. On the other hand, let
so that $\mathrm {Ind}_{P({\mathbb {Q}}_p)}^{H({\mathbb {Q}}_p)}(\rho )=\varinjlim _{K} S_{K}$. We may, and will, restrict to pro-$p$ compact open subgroups $K\subset H({\mathbb {Z}}_p)$; to complete the proof, we will show that the composite $a_{\iota ^*}\circ q_K^*$ induces an isomorphism $H^i(I_{K}, {\mathbb {F}}_\ell ) \simeq S_{K}$.
Choose a set of representatives $R=\{h_1, \ldots, h_r\}$ of the (finite) double coset $P({\mathbb {Q}}_p) \backslash H({\mathbb {Q}}_p)/K$ such that each $h_j$ belongs to $H({\mathbb {Z}}_p)$ (this is possible because of the Iwasawa decomposition of $H({\mathbb {Q}}_p)$). Evaluation at elements of $R$ yields an injection $S_K \hookrightarrow V^R$; an explicit computation shows that the image is $\bigoplus _{R}V^{\Gamma _j}$, where $\Gamma _j:=P({\mathbb {Q}}_p) \cap h_jKh_j^{-1}$. Consider the composite of the map $a_{\iota ^*}\circ q_K^*$ and of the injection $S_K \hookrightarrow V^R$, and let $\phi _j$ be its $h_j$th component. Then $\phi _j$ sends $c\in H^i(I_K, {\mathbb {F}}_\ell )$ to $\iota ^*\circ h_j^* \circ q_K^*(c)$.
We can write
The isomorphism is induced on the $h_j$th component by the composite of the map
given by right multiplication by $h_j$ and the map
sending everything to the identity on the second component. Therefore, via the isomorphism in (6.3.3.1), the map $\phi _j$ is identified with the pullback $H^i(\underline {\Gamma _j}\backslash I, {\mathbb {F}}_\ell )\rightarrow H^i(I, {\mathbb {F}}_\ell )$.
It remains to show that each of the pullback maps above induces an isomorphism $H^i(\underline {\Gamma _j}\backslash I, {\mathbb {F}}_\ell )\xrightarrow {\sim } V^{\Gamma _j}$. Each group $\Gamma _j$ is contained in $P({\mathbb {Z}}_p)$, hence the action of $\Gamma _j/(\Gamma _j\cap C)$ on $I$ is free. Therefore, as $K$ is a pro-$p$ group and $p \neq \ell$, the desired isomorphism follows from [Reference WeinsteinWei17, Proposition 4.3.2] and [Reference Caraiani, Gulotta, Hsu, Johansson, Mocz, Reinecke and ShihCGH+20, Theorem 2.2.7].
7. The structure of the cohomology in the non-Eisenstein case
The aim of this section is to prove our main results on the cohomology of Hilbert modular varieties after localisation at a non-Eisenstein maximal ideal. These are Theorems 7.1.1 and 7.1.6 stated below. We also establish analogous results for quaternionic Shimura varieties: see Theorem 7.5.2.
7.1 Main results: statements
Theorem 7.1.1 Let $\ell >2$ be a prime, $K\subset G({\mathbb {A}}_f)$ a neat compact open and $\mathfrak {m} \subset \mathbb {T}$ a maximal ideal in the support of $H^i(Sh_K(G), {\mathbb {F}}_{\ell })$. Let $\bar {\rho }_{\mathfrak {m}}$ be the Galois representation attached to $\mathfrak {m}$ by Theorem 2.2.1. Assume that the image of $\bar {\rho }_{\mathfrak {m}}$ is not solvable. Then $H^i(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}=H^i_c(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-zero only for $i=g$.
Corollary 7.1.2 With the same notation and assumptions as in Theorem 7.1.1, we have $H^i(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}\neq 0$ if and only if $i=g$, and $H^g(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}$ is torsion-free. The same is true for compactly supported cohomology.
Proof. Looking at the long exact sequence in Betti cohomology coming from the short exact sequence $0 \rightarrow {\mathbb {Z}}_{\ell } \rightarrow {\mathbb {Z}}_{\ell } \rightarrow {\mathbb {F}}_{\ell }\rightarrow 0$ we see that multiplication by $\ell$ is surjective on $H^i(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}$ if $i \neq g$, hence $H^i(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}=0$ for $i \neq g$. On the other hand, we have
as the first term vanishes, we deduce that $H^g(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}$ is torsion-free, hence free. Finally, the cokernel of the map $H^g(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m} \rightarrow H^g(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}$ injects into $H^{g+1}(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}=0$, hence $H^g(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m} \neq 0$. The result for $H^*_{\rm c}(Sh_K(G), {\mathbb {Z}}_{\ell })_\mathfrak {m}$ follows as in Lemma 2.3.1.
To proceed, we make the following definition.
Definition 7.1.3
(i) Let $v$ be a place of $F$ above a prime $p\not =\ell$ which splits completely in $F$. We say that $\bar {\rho }_\mathfrak {m}$ is generic at $v$ if it is unramified at $v$ and the eigenvalues of Frobenius at $v$ have ratio different from $p^{\pm 1}$.
(ii) Let $p \neq \ell$ be a prime. We say that $p$ is a decomposed generic prime for $\bar {\rho }_\mathfrak {m}$ if $p$ splits completely in $F$ and $\bar {\rho }_{\mathfrak {m}}$ is generic at $v$ for every place $v$ of $F$ above $p$.
(iii) We say that $\bar {\rho }_{\mathfrak {m}}$ is decomposed generic if there exists a prime $p \neq \ell$ which is decomposed generic for $\bar {\rho }_{\mathfrak {m}}$.
7.1.4
Assume that $\bar {\rho }_{\mathfrak {m}}$ is generic at some place $v$ of $F$. Then any characteristic zero lift of the restriction of $\bar {\rho }_{\mathfrak {m}}$ to $\Gamma _{F_v}$ cannot be associated via the local Langlands correspondence to an irreducible smooth representation of $\operatorname {GL}_2(F_v)$ which transfers to the non-split quaternion algebra over $F_v$.
Notation 7.1.5 Let $p \neq \ell$ be a prime which splits completely in $F$ and such that $\bar {\rho }_\mathfrak {m}$ is unramified at every place of $F$ above $p$. We will denote by $\delta _p(\mathfrak {m})$ the number of places above $p$ at which $\bar {\rho }_\mathfrak {m}$ is not generic.
Theorem 7.1.6 Let $\ell >2$ be a prime. Let $p \neq \ell$ be an odd prime which splits completely in $F$ and such that $K=K^pK_p$ with $K_p$ hyperspecial. Let $\mathfrak {m} \subset \mathbb {T}$ be a non-Eisenstein maximal ideal. Then $H^*_c(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}=H^*(Sh_K(G), {\mathbb {F}}_{\ell })_\mathfrak {m}$ vanishes outside the interval $[g-\delta _p(\mathfrak {m}), g+\delta _p(\mathfrak {m})]$.
Remark 7.1.7 For a maximal ideal $\mathfrak {m} \subset \mathbb {T}$ in the support of $H^i(Sh_K(G), {\mathbb {F}}_{\ell })$, the projective image $I$ of the Galois representation $\bar {\rho }_\mathfrak {m}$ is a finite subgroup of $\operatorname {PGL}_2(\bar {{\mathbb {F}}}_\ell )$. By Dickson's theorem, cf. [Reference Darmon, Diamond and TaylorDDT97, Theorem 2.47 (b)], the group $I$ is either conjugate to a subgroup of the upper triangular matrices, or to $\operatorname {PGL}_2({\mathbb {F}}_{\ell ^k})$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, for some $k\geq 1$, or it is isomorphic to one of $D_{2n}$, for some $n\in {\mathbb {Z}}_{> 1}$ prime to $\ell$, $A_4$, $S_4$ or $A_5$. It follows that the image of $\bar {\rho }_\mathfrak {m}$ is not solvable if and only if the following holds:
(i) if $\ell =3$, then $I$ is isomorphic to $A_5$ or it contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_9)$;
(ii) if $\ell >3$, then $I$ is isomorphic to $A_5$ or it contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_{\ell })$.
Theorem 7.1.1 follows from Theorem 7.1.6 in view of the following lemma (more precisely, observe that the proof of the lemma allows to produce $p$ as in Definition 7.1.3(iii) satisfying the conditions of Theorem 7.1.6).
Lemma 7.1.8 Assume that $\ell >2$ and that the image of $\bar {\rho }_{\mathfrak {m}}$ is not solvable. Then $\bar {\rho }_{\mathfrak {m}}$ is decomposed generic in the sense of Definition 7.1.3.
Proof. This is a variation of [Reference Allen and NewtonAN20, Lemma 2.3]; following [Reference Allen and NewtonAN20, Lemma 2.3], we prove that there are infinitely many primes $p\equiv 1 \pmod {\ell }$, totally split in $F$, and such that $\bar {\rho }_\mathfrak {m}$ is generic at every place above $p$. This is deduced from our large image assumption using the Chebotarev density theorem.
We first make some preliminary reductions. Let $\tilde {F}$ be the normal closure of $F$ in ${\mathbb {C}}$; notice that $\tilde {F}$ is also a totally real field. Let $\mathrm {pr}: \operatorname {GL}_2(\bar {{\mathbb {F}}}_{\ell })\rightarrow \operatorname {PGL}_2(\bar {{\mathbb {F}}}_{\ell })$ be the projection map. As observed before the statement of the theorem, the image $I$ of
is isomorphic to $A_5$, or conjugate to one of $\operatorname {PGL}_2({\mathbb {F}}_{\ell ^k})$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, where $k\geq 2$ if $\ell = 3$ and $k\geq 1$ if $\ell >3$. We claim that the same is true for the image $\tilde {I}$ of $\mathrm {pr} \circ \bar {\rho }_{\mathfrak {m}|\Gamma _{\tilde {F}}}: \Gamma _{\tilde {F}} \rightarrow \operatorname {PGL}_2(\bar {{\mathbb {F}}}_\ell )$. Since $\tilde {F}/F$ is Galois, the group $\tilde {I}$ is a normal subgroup of $I$.
(i) Assume first that the group $I$ is isomorphic to $A_5$. Since $A_5$ is simple and $\tilde {I}$ is a normal subgroup of $I$, it is enough to show that $\tilde {I}$ is non-trivial. This is true because $\tilde {I}$ contains the image under $\mathrm {pr}\circ \bar {\rho }_{\mathfrak {m}|\Gamma _{\tilde {F}}}$ of any complex conjugation in $\Gamma _{\tilde {F}}$, which is conjugate to the matrix $(\begin{smallmatrix} 1 & 0\\ 0 & -1 \end{smallmatrix})$ because $\bar {\rho }_{\mathfrak {m}}$ is totally odd.
(ii) Assume now that the group $I$ is conjugate to $\operatorname {PGL}_2({\mathbb {F}}_{\ell ^k})$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$. We conjugate everything so that $I$ is identified with $\operatorname {PGL}_2({\mathbb {F}}_{\ell ^k})$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$ inside $\operatorname {PGL}_2(\bar {{\mathbb {F}}}_\ell )$. It is enough to prove that $\tilde {I}\supseteq \operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$. As the representation $\bar {\rho }_{\mathfrak {m}}$ is totally odd, the image via $\bar {\rho }_{\mathfrak {m}|\Gamma _{\tilde {F}}}$ of any complex conjugation $c\in \Gamma _{\tilde {F}}$ is a non-scalar semisimple element. As a normal subgroup of $I$, the group $\tilde {I}$ contains the projective image of every $\operatorname {SL}_2({\mathbb {F}}_{\ell ^k})$-conjugate of $\bar {\rho }_{\mathfrak {m}}(c)$. In particular, $\tilde {I}\cap \operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$ contains the ratio of any two distinct such conjugates and is, therefore, a non-trivial normal subgroup of $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$. Finally, the groups $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, with $k\geq 2$ if $\ell =3$ and $k\geq 1$ if $\ell >3$, are simple. Therefore, $\tilde {I}\supseteq \operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$.
This proves the claim. Up to replacing $\tilde {F}$ by a finite abelian extension $F'$ and conjugating $\bar {\rho }_{\mathfrak {m}}$, we may ensure that the image $I'$ of $\mathrm {pr} \circ \bar {\rho }_{\mathfrak {m}|\Gamma _{F'}}$ equals either $A_5$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, with $k\geq 2$ if $\ell =3$ and $k\geq 1$ if $\ell >3$. As $A_5$ and $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$ are both simple, $I'$ is unchanged if we replace $F'$ by its normal closure. For the same reason we may adjoin $\zeta _{\ell }$ to $F'$ without changing $I'$.
Let $\Gamma$ denote either one of the finite simple groups $A_5$ or $\operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$. Let $L$ be the normal closure of the extension of $F'$ cut out by $I'$. Since $\Gamma$ is simple, Goursat's lemma implies that $\operatorname {Gal}(L/F')\simeq \Gamma ^t$ for some $t\geq 1$. We claim that we can choose an element $1\neq g\in \Gamma$ which is semisimple when viewed as an element of $\operatorname {PGL}_2(\bar {{\mathbb {F}}}_{\ell })$. In the case $\Gamma = \operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, this is clear. In the case $\Gamma = A_5$, choose any element of order $2$; since $\ell \not =2$, such an element must be semisimple. The Chebotarev density theorem ensures the existence of a place $\mathfrak {p}$ of $F'$ with residue field ${\mathbb {F}}_p$ with $p \neq \ell$ unramified in $F$ and such that $\mathrm {Frob}_\mathfrak {p}^{L/F'}$ is conjugate to $(g, g, \ldots, g)$. Since $F'/{\mathbb {Q}}$ is Galois, $p$ is totally split in $F'$. We claim that, for every place $\mathfrak {p}'$ of $F'$ above $p$, the element $\bar {\rho }_\mathfrak {m}(\mathrm {Frob}_{\mathfrak {p}'})$ is semisimple and different from the identity in $\operatorname {PGL}_2(\bar {{\mathbb {F}}}_{\ell })$. In the case $\Gamma = \operatorname {PSL}_2({\mathbb {F}}_{\ell ^k})$, this follows as in [Reference Allen and NewtonAN20, Lemma 2.3]. In the case $\Gamma = A_5$, the argument in [Reference Allen and NewtonAN20, Lemma 2.3] shows that each such element has order $2$ in $\operatorname {PGL}_2(\bar {{\mathbb {F}}}_{\ell })$, which implies that it must also be semisimple and different from the identity. As $\zeta _{\ell } \in F'$ we have $p \equiv 1 \pmod {\ell }$, hence the eigenvalues of each $\bar {\rho }_\mathfrak {m}(\mathrm {Frob}_{\mathfrak {p}'})$ cannot have ratio $p^{\pm 1}$.
7.2 Proof of Theorem 7.1.6
7.2.1 Step 1: setup and choice of the auxiliary data
Note that the quantity $\delta _p(\mathfrak {m}) = \delta _p(\mathfrak {m}^\vee )$. By Lemma 2.3.1 it suffices to show the following implication:
Choose an auxiliary $CM$ extension $E$ of $F$ such that every $\mathfrak {p} \in \Sigma _p$ is inert in $E$, and choose $K_E=(\mathcal {O}_E\otimes {\mathbb {Z}}_p)^\times K_E^{p}\subset T_E({\mathbb {A}}_f)$ sufficiently small with respect to $K$. With the notation of § 3.1.3, consider the unitary group $H:=H_{\emptyset }$ and let $U \subset H({\mathbb {A}}_f)$ be the image of $K \times K_E$. Recall that the Hecke algebra $\mathbb {T}$ (defined in § 3.2.6) acts on the cohomology of $Sh_{U}(H)$, and Corollary 3.2.9 ensures that, for $i \geq 0$,
Therefore, for the sake of proving Theorem 7.1.6, we may (and will) work with $Sh_U(H)$. Let $\overline {Sh}_U(H)$ be the base change to $\bar {{\mathbb {F}}}_p$ of its integral model. We have isomorphisms, for $i \geq 0$,
The first is obtained as in [Reference Lan and StrohLS18, Corollary 5.20]; the second follows from the fact that the complex of nearby cycles $R\Psi {\mathbb {F}}_{\ell }$ is quasi-isomorphic to the constant sheaf ${\mathbb {F}}_{\ell }$ as the integral model is smooth. Hence, it suffices to show the implication
7.2.2 Step 2: the Newton stratification
We have a Newton stratification on $\overline {Sh}_U(H)$ indexed by elements $b=(b_1, \ldots, b_g)$ with $b_j \in B(H_{\mathfrak {p}_j}, \mu _{\mathfrak {p}_j})$. Recall that each $B(H_{\mathfrak {p}_j}, \mu _{\mathfrak {p}_j})$ consists of one $\mu$-ordinary and one basic element. We denote by $\overline {Sh}_U(H)^b \subset \overline {Sh}_U(H)$ the stratum corresponding to $b$. More generally, for each $0 \leq k \leq g$ and every $c \in \prod _{j \leq k}B(H_{\mathfrak {p}_j}, \mu _{\mathfrak {p}_j})$ we let $\overline {Sh}_U(H)^c \subset \overline {Sh}_U(H)$ be the union of the Newton strata corresponding to elements $b=(b_1, \ldots, b_g)$ such that $(b_1, \ldots, b_k)=c$. In particular, for $k=0$ we obtain $\overline {Sh}_U(H)$ and for $k=g$ we recover Newton strata.
As we are excluding from $\mathbb {T}$ the Hecke operators at places above $p$, the Hecke algebra acts on the cohomology of each stratum. The first (elementary) observation is that it suffices to show (7.2.1.2) for each Newton stratum.
Lemma 7.2.3 Assume that $H^i_{\rm c}(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for every $i< g-\delta _p(\mathfrak {m})$ and every $b \in B(H_{{\mathbb {Q}}_p}, \mu )$. Then $H^i_{\rm c}(\overline {Sh}_U(H), {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for $i< g-\delta _p(\mathfrak {m})$.
Proof. This follows from additivity of compactly supported cohomology. To be precise, we show by descending induction on $0 \leq k \leq g$ that
By hypothesis the statement is true for $k=g$. Now take $k< g$ and assume that the statement is true for $k+1$. Take $c \in \prod _{j \leq k}B(H_{\mathfrak {p}_j}, \mu _{\mathfrak {p}_j})$. Let $o$ (respectively, $b$) be the non-basic (respectively, basic) element in $B(H_{\mathfrak {p}_{k+1}}, \mu _{\mathfrak {p}_{k+1}})$ and consider $(c, o), (c, b) \in \prod _{j \leq k+1}B(H_{\mathfrak {p}_j}, \mu _{\mathfrak {p}_j})$. We have
furthermore, $\overline {Sh}_U(H)^{(c, o)}$ is open in $\overline {Sh}_U(H)^c$ and $\overline {Sh}_U(H)^{(c, b)}$ is the closed complement. By induction, we know that $H^i_c(\overline {Sh}_U(H)^{(c, o)}, {\mathbb {F}}_{\ell })_\mathfrak {m}=H^i_c(\overline {Sh}_U(H)^{(c, b)}, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for $i< g-\delta _p(\mathfrak {m})$. The exact sequence
implies that $H^i_c(\overline {Sh}_U(H)^{c}, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for $i< g-\delta _p(\mathfrak {m})$.
We need to show that the assumption of the lemma holds true in our situation. The first key ingredient is the following.
Lemma 7.2.4 Let $b \in B(H_{{\mathbb {Q}}_p}, \mu )$.
(i) If $b$ is not the $\mu$-ordinary element, then the stratum $\overline {Sh}_U(H)^b$ is smooth, affine and of dimension the number of non-basic coordinates of $b$.
(ii) If $b$ is the $\mu$-ordinary element, then $\overline {Sh}_U(H)^b$ is smooth of dimension $g$, and the partial minimal compactification of $\overline {Sh}_U(H)^b$ (i.e. the union of $\overline {Sh}_U(H)^b$ and the cusps in the minimal compactification of $\overline {Sh}_U(H)$) is affine.
Proof. The dimension of strata can be obtained from [Reference Tian and XiaoTX16, Proposition 4.7]. As $p$ splits completely in $F$ Newton strata coincide with Ekedahl–Oort strata. Each of them is smooth by [Reference Shen and ZhangSZ22, Theorem 3.4.7]. Furthermore, recall that $\overline {Sh}_U(H)$ is a finite union of quotients of connected components of integral models of Hodge-type Shimura varieties by finite groups. Each Ekedahl–Oort stratum in $\overline {Sh}_U(H)$ decomposes accordingly, hence its partial minimal compactification is affine by [Reference Goldring and KoskivirtaGK19, Proposition 6.3.1] (see also [Reference BoxerBox15]). Finally, the $\mu$-ordinary stratum is the only one intersecting the boundary, hence the lemma follows.
Corollary 7.2.5 Let $b \in B(H_{{\mathbb {Q}}_p}, \mu )$ be such that $\dim \overline {Sh}_U(H)^b\geq g-\delta _p(\mathfrak {m})$. Then for every $i< g-\delta _p(\mathfrak {m})$ we have $H^i_c(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$.
Proof. Let us first assume that $b$ is not the $\mu$-ordinary element and let us set $d_b:=\dim \overline {Sh}_U(H)^b$. By Artin vanishing $H^i(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })=0$ for $i>d_b$, and by Poincaré duality $H^i_c(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })=0$ for $i< d_b$. In particular, $H^i_c(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for $i< g-\delta _p(\mathfrak {m})$.
Now let us consider the ordinary stratum $\overline {Sh}_U(H)^b$ and its partial minimal compactification $\overline {Sh}_U(H)^{b, *}$, with boundary $\partial$. Let $j^b: \overline {Sh}_U(H)^b \rightarrow \overline {Sh}_U(H)^{b, *}$ and $i^b: \partial \rightarrow \overline {Sh}_U(H)^{b, *}$ be the inclusions. By Artin vanishing $H^i(\overline {Sh}_U(H)^{b, *}, j^b_!{\mathbb {F}}_{\ell })=0$ for $i>g$, and by Verdier duality $H^i_c(\overline {Sh}_U(H)^{b, *}, Rj^b_*{\mathbb {F}}_{\ell })=0$ for $i< g$. Finally, we have an exact sequence
To end the proof it suffices to show that $H^*_c(\partial, i^{b, *}Rj^b_*{\mathbb {F}}_{\ell })_\mathfrak {m}=0$. Denoting by $j: \overline {Sh}_U(H) \rightarrow \overline {Sh}_U(H)^{*}$ and $i: \partial \rightarrow \overline {Sh}_U(H)^{*}$ the inclusions we have $i^{b, *}Rj^{b}_*{\mathbb {F}}_\ell \simeq i^{*}Rj_*{\mathbb {F}}_\ell$. It follows that it suffices to prove that, after localisation at $\mathfrak {m}$, the maps $H^*_c(\overline {Sh}_U(H), {\mathbb {F}}_\ell )\rightarrow H^*_c(\overline {Sh}_U(H)^{*}, Rj_*{\mathbb {F}}_\ell )$ are bijective. In other words, we have to show that the natural maps
are isomorphisms. Using [Reference Lan and StrohLS18, Corollary 5.20] we see that we can replace $\overline {Sh}_U(H)$ by $Sh_U(H)$; since $\mathfrak {m}$ is non-Eisenstein, the conclusion then follows from Lemma 2.3.1 and Corollary 3.2.9.
To show Theorem 7.1.6 it remains to prove the following result.
Proposition 7.2.6 Let $b \in B(H_{{\mathbb {Q}}_p}, \mu )$ and let $\mathfrak {m} \subset \mathbb {T}$ be a non-Eisenstein maximal ideal. If $\dim \overline {Sh}_U(H)^b< g-\delta _p(\mathfrak {m})$, then for every $i\geq 0$ we have $H^i(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$.
Indeed, applying the above proposition to $\mathfrak {m}^\vee$ and using Corollary 7.2.5 we obtain that $H^i_c(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for $i< g-\delta _p(\mathfrak {m})$ and for every $b \in B(H_{{\mathbb {Q}}_p}, \mu )$. By Lemma 7.2.3 we conclude that $H^i_{\rm c}(\overline {Sh}_U(H), {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for $i< g-\delta _p(\mathfrak {m})$.
Finally, we will deduce Proposition 7.2.6 from the following result, whose proof will be given below.
Proposition 7.2.7 If $\dim \overline {Sh}_U(H)^b< g-\delta _p(\mathfrak {m})$, then $H^i(\mathrm {Ig}^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for every $i$.
7.2.8
Assuming Proposition 7.2.7, let us prove Proposition 7.2.6. Observe that the stratum $\overline {Sh}_U(H)^b$ consists of a unique leaf; let $\mathbb {X}^b$ be the $p$-divisible group attached to a geometric point in the leaf, and $\Gamma ^b$ the automorphism group of $\mathbb {X}^b$ (respecting extra structures). Let $Y_U(H)_{\bar {{\mathbb {F}}}_p}^{b, \mathrm {perf}}$ be the perfection of $Y_U(H)_{\bar {{\mathbb {F}}}_p}^b$; the forgetful map $\overline {\mathrm {Ig}}^b\rightarrow Y_U(H)_{\bar {{\mathbb {F}}}_p}^b$ factors through a map $\overline {\mathrm {Ig}}^b\rightarrow Y_U(H)_{\bar {{\mathbb {F}}}_p}^{b, \mathrm {perf}}$, which is a $\Gamma ^b$-torsor (cf. [Reference Caraiani and ScholzeCS19, Proposition 2.2.6]). For $u \in \mathcal {O}_{E}^{\times }\cap U^p$, the action of $N_{E/F}(u)$ on $\overline {\mathrm {Ig}}^b$ changing the polarisation agrees with the action of $u^{-1}$ on $\overline {\mathrm {Ig}}^b$ via the inclusion $\mathcal {O}_{E}^{\times } \hookrightarrow \Gamma ^b$. Hence, the induced map $\mathrm {Ig}^b\rightarrow \overline {Sh}_U(H)^{b, \mathrm {perf}}$ is a torsor for the group $\Gamma ^b/\varprojlim _k(\mathcal {O}_E^{\times }\cap U/\{u \in \mathcal {O}_E^{\times }\cap U \mid u \equiv 1 \pmod {p^k}\})$. Therefore, there is a Hecke-equivariant Hochschild–Serre spectral sequence relating the cohomology of $\mathrm {Ig}^b$ and the cohomology of $\overline {Sh}_U(H)^{b, \mathrm {perf}}$. The latter agrees with étale cohomology of $\overline {Sh}_U(H)^b$ by topological invariance of the étale site; hence, if $H^i(\mathrm {Ig}^b, {\mathbb {F}}_{\ell })_\mathfrak {m}=0$ for every $i$, then the same is true for $H^i(\overline {Sh}_U(H)^b, {\mathbb {F}}_{\ell })_\mathfrak {m}$.
7.3 The excision triangle for diamonds
In the proof of Proposition 7.2.7, given in the next section, we will make use of the long exact sequence relating, under suitable assumptions, sheaves on a diamond to their restriction to an open subdiamond and its closed complement. The existence of such an exact sequence is well-known; for the reader's convenience, we will briefly explain how to obtain it.
7.3.1
Fix a locally spatial diamond $X$; let $X_{\mathrm {\acute {e}t}}$ be the étale site of $X$, defined in [Reference ScholzeSch17, Definition 14.1], and $|X|$ the underlying topological space of $X$, defined in [Reference ScholzeSch17, Definition 11.14]. One can attach to each $x \in |X|$ a quasi-pro-étale map $\bar {x}=\mathrm {Spa}(C(x), C(x)^+)\rightarrow X$, with $C(x)$ an algebraically closed perfectoid field, mapping the closed point of $\mathrm {Spa}(C(x), C(x)^+)$ to $x$ (see [Reference ScholzeSch17, Proposition 14.3] and [Reference Caraiani, Gulotta, Hsu, Johansson, Mocz, Reinecke and ShihCGH+20, Lemma 2.2.2]). We call $\bar {x}$ a geometric point of $X$ (with the important caveat that as a set $\bar {x}$ may not be a singleton), and we denote by $F_{\bar {x}}$ the stalk of a sheaf $F$ at $\bar {x}$. By [Reference ScholzeSch17, Proposition 14.3] we may check if a sequence of étale sheaves on $X$ is exact looking at stalks at each geometric point.
7.3.2
Fix an open subspace of $|X|$, corresponding, by [Reference ScholzeSch17, Proposition 11.15], to a subdiamond $j: U \rightarrow X$; assume that the closed complement $|X|\smallsetminus |U|$ is generalising, so that, by [Reference Anschütz, Gleason, Lourenço and RicharzAGLR22, Lemma 2.7] and [Reference ScholzeSch17, Proposition 11.20], it is the underlying topological space of a canonical locally spatial subdiamond $i: Z \rightarrow X$.Footnote 6 Since $|Z|$ is generalising, geometric points of $X$ are a disjoint union of geometric points of $U$ and of $Z$. We have the extension by zero functor $j_!: \mathrm {Ab}(U_{\mathrm {\acute {e}t}})\rightarrow \mathrm {Ab}(X_{\mathrm {\acute {e}t}})$, defined as for schemes (cf. the discussion before [Reference Caraiani, Gulotta, Hsu, Johansson, Mocz, Reinecke and ShihCGH+20, Lemma 2.2.6]), which is exact and left-adjoint to $j^*$. The stalk of $j_!F$ at $x \in |U|$ (respectively, $x \in |Z|$) is isomorphic to $F_{\bar {x}}$ (respectively, is zero).
Lemma 7.3.3 Let $x \in |X|$ and let $\bar {x}$ be the associated geometric point; let $F$ be an étale sheaf (of abelian groups) on $Z$. If $x \not \in |Z|$, then $(i_*F)_{\bar {x}}=0$; if $x \in |Z|$, then $(i_{*}F)_{\bar {x}}=F_{\bar {x}}$.
Proof. If $x \not \in |Z|$, then $x \in |U|$, hence there is a cofinal systems of étale neighbourhoods $V \rightarrow X$ of $x$ factoring through $U$; therefore, $i_*F(V)=0$ and $(i_*F)_{\bar {x}}=0$. Now take $x \in |Z|$; then $(i_*F)_{\bar {x}}=\varinjlim _{V} F(V \times _X Z)$, where $V$ runs over the objects $V\rightarrow X \in X_{\mathrm {\acute {e}t}}$ through which $\bar {x}$ factors. We may restrict to $V$ spatial and such that $V \rightarrow X$ factors through a fixed spatial open subdiamond of $X$. Using [Reference ScholzeSch17, Proposition 14.9], the description of $\bar {x}$ before [Reference Caraiani, Gulotta, Hsu, Johansson, Mocz, Reinecke and ShihCGH+20, Lemma 2.2.2], and the fact that $\bar {x} \rightarrow X$ factors through $Z$, we have
Proposition 7.3.4 Let $X$ be a locally spatial diamond, and $j: U \rightarrow X$ an open subdiamond with generalising closed complement underlying a subdiamond $i: Z\rightarrow X$. For every étale sheaf $F$ of abelian groups on $X$ the sequence
is exact.
Proof. It suffices to check this on stalks at each geometric point $\bar {x} \rightarrow X$. If $\bar {x}$ factors through $U$ we get $0 \rightarrow F_{\bar {x}}\xrightarrow {\mathrm {Id}} F_{\bar {x}}\rightarrow 0 \rightarrow 0$. If it factors through $Z$, then $(j_!j^{*}F)_{\bar {x}}=0$. On the other hand, setting $G=i^{*}F$ we have $(i_{*}G)_{\bar {x}}=G_{\bar {x}}$ by the previous lemma, and $G_{\bar {x}}=F_{\bar {x}}$. Hence we get $0 \rightarrow 0 \rightarrow F_{\bar {x}}\xrightarrow {\mathrm {Id}} F_{\bar {x}}\rightarrow 0$.
7.4 Proof of Proposition 7.2.7
7.4.1
Let $b=(b_\mathfrak {p})_{\mathfrak {p} \in \Sigma _p}\in B(H_{{\mathbb {Q}}_p}, \mu )$ be an element such that $R\Gamma (\mathrm {Ig}^b, {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-trivial and such that the dimension $d^{\mathrm {min}}$ of $\overline {Sh}_U(H)^b$ is as small as possible. Let $\varepsilon$ be the cardinality of the set $T\subset \Sigma _p$ consisting of places $\mathfrak {p}$ such that $b_\mathfrak {p}$ is basic. Then $d^{\mathrm {min}}=g-\varepsilon$, so we need to prove that
If $\varepsilon =0$ there is nothing to prove; hence let us assume $\varepsilon >0$, so that $T$ is non-empty. Let $H_T$ be the unitary group attached to $T$, defined in § 3.1.3, and $\mathrm {Ig}_T^{\mathrm {ord}}$ the associated $\mu _T$-ordinary Igusa variety. Consider the Hodge–Tate period map
Our assumption and Theorem 4.2.4 imply that $R\Gamma (\mathrm {Ig}_T^{\mathrm {ord}}, {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-trivial. Because of Proposition 5.3.1 we deduce that $(R\pi _{\mathrm {HT}, *}^T {\mathbb {F}}_{\ell })_\mathfrak {m}$ has non-trivial cohomology on the $\mu _T$-ordinary stratum. Better, we have the following.
Lemma 7.4.2 The $\mu _T$-ordinary stratum is the only one where $(R\pi _{\mathrm {HT}, *}^T{\mathbb {F}}_{\ell })_\mathfrak {m}$ has non-zero cohomology.
Proof. Assume the contrary. Then using Proposition 5.3.1 we find that there is a non-ordinary element $b'_T \in B(H_{T, {\mathbb {Q}}_p}, \mu _T)$ such that $H^*(\mathrm {Ig}^{b'_T}_T, {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-zero. Consider the element $b' \in B(H_{{\mathbb {Q}}_p}, \mu )$ which is basic precisely at places in $T$ and at places outside $T$ where $b'_T$ is basic. By Theorem 4.2.4 the cohomology $H^*(\mathrm {Ig}^{b'}, {\mathbb {F}}_{\ell })_\mathfrak {m}$ is not identically zero; however the dimension of $\overline {Sh}_U(H)^{b'}$ is strictly smaller than the dimension of $\overline {Sh}_U(H)^b$, hence we obtain a contradiction.
7.4.3
We now come back to the proof of Proposition 7.2.7. Perversity of the complex $R\pi ^T_{\mathrm {HT}, *}{\mathbb {F}}_{\ell }[g-\varepsilon ]$ and the fact that it is concentrated on one stratum after localisation at $\mathfrak {m}$ imply that $H^i(\mathrm {Ig}_T^{\mathrm {ord}}, {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-zero only in middle degree $g-\varepsilon$ (cf. [Reference Caraiani and ScholzeCS17, Corollary 6.1.4]). Theorem 6.3.3 (together with the fact that smooth parabolic induction of a non-zero representation is non-zero) implies that
Let $Z\subset \mathscr {F}\ell _{H_{T}, \mu _T}$ be the $\mu _T$-ordinary locus, and $V:=\mathscr {F}\ell _{H_{T}, \mu_T^{-1}}\smallsetminus Z$. We have an inclusion
which induces a bijection on rank one points. The ordinary locus $\mathcal {S}h_{U^p}(H_T)^{b^\mathrm {ord}}$ is open and quasi-compact, as it is the preimage of a quasi-compact open subspace in the special fibre via the specialisation map, which is continuous and spectral. By [Reference Caraiani and ScholzeCS17, Lemma 4.4.2] the map induced in cohomology by (7.4.3.2) is an isomorphism, hence the equivalence in (7.4.3.1) holds true for the cohomology of $(\pi _{\mathrm {HT}}^{T})^{-1}(Z)$ as well. Let $i_Z: Z \rightarrow \mathscr {F}\ell _{H_{T}, \mu_T^{-1}}$ and $i_V : V \rightarrow \mathscr {F}\ell _{H_{T}, \mu _T}$ be the inclusion maps. The assumptions of Proposition 7.3.4 are satisfied, hence for every $j \geq 0$ we have an exact sequence
Lemma 7.4.2 ensures that the first term vanishes after localisation at $\mathfrak {m}$; therefore, we deduce that $H^i(\mathscr {F}\ell _{H_{T}, \mu_T^{-1}}, R^j\pi ^T_{\mathrm {HT}, *}{\mathbb {F}}_{\ell })_\mathfrak {m}=H^i(Z, R^j\pi ^T_{\mathrm {HT}, *}{\mathbb {F}}_{\ell })_\mathfrak {m}$. The outcome of our discussion is that cohomology of $\mathcal {S}h_{U^p}(H_T)$ coincides with cohomology of its ordinary locus, after localisation at $\mathfrak {m}$; hence $H^i(\mathcal {S}h_{U^p}(H_T), {\mathbb {F}}_{\ell })_\mathfrak {m} \neq 0$ if and only if $i=g-\varepsilon$.
Now $\mathcal {S}h_{U^p}(H_T)$ is the inverse limit (as a diamond) of the spaces $\mathcal {S}h_{U^pU_{T, p}}(H_T)$ for $U_{T, p}\subset H_T({\mathbb {Q}}_p)$ running over compact open subgroups. There is a cofinal system of subgroups $U_{T, p}$ which are images in $H_T({\mathbb {Q}}_p)$ of subgroups of the form $K_{T, p}\times K_{E, p}\subset G_T({\mathbb {Q}}_p)\times T_E({\mathbb {Q}}_p)$, where $K_{E, p}$ is such that $K_{E, p}K_{E}^p$ is sufficiently small with respect to $K_{T, p}K^p$, in the sense of Definition 3.2.2. For $U_{T, p}$ of this form and small enough, we must have
where the first equality holds because a small enough subgroup $U_{T, p}$ is a pro-$p$ group, hence the map from the cohomology of $\mathcal {S}h_{U^pU_{T, p}}(H_T)$ to the cohomology of $\mathcal {S}h_{U^p}(H_T)$ is injective. The argument in the proof of Corollary 7.1.2 shows that $H^{g-\varepsilon }(Sh_{U^pU_{T, p}}(H_T), {\mathbb {Z}}_{\ell })_\mathfrak {m}$ is non-zero and torsion free, therefore we deduce that
Applying Corollary 3.2.9 once more we obtain that $H^{g-\varepsilon }(Sh_{K^pK_{T, p}}(G_T), {\mathbb {Q}}_{\ell })_\mathfrak {m}\neq 0$. We claim that this implies that $\bar {\rho }_\mathfrak {m}$ cannot be generic at places in $T$; this yields the desired inequality $\varepsilon \leq \delta _p(\mathfrak {m})$ and ends the proof of Proposition 7.2.7.
To justify our claim, recall that $H^{g-\varepsilon }(Sh_{K^pK_{T, p}}(G_T), \bar {{\mathbb {Q}}}_{\ell })$ can be described in terms of automorphic representations of $G_T$ as in [Reference NekovářNek18, (5.9)–(5.11)]. The Hecke algebra acts on the universal part of cohomology (corresponding to one-dimensional automorphic representations, and called case (A) in [Reference NekovářNek18]) via the degree character. Hence, this part of cohomology vanishes after localisation at $\mathfrak {m}$, since $\mathfrak {m}$ is non-Eisenstein. Therefore, as in [Reference NekovářNek18, (5.11)(B)], there is an automorphic representation $\pi _T$ of $G_T$ which transfers to an automorphic representation $\pi$ of $\operatorname {GL}_{2, F}$ attached to a (holomorphic) cuspidal Hilbert newform $f$ such that almost all the Hecke eigenvalues of $f$ modulo $\ell$ are given by the image of the map $\mathbb {T} \rightarrow \mathbb {T}/\mathfrak {m}$. Letting $\rho _\pi : \Gamma _F \rightarrow \operatorname {GL}_2(\bar {{\mathbb {Q}}}_{\ell })$ be the Galois representation attached to $\pi$, we deduce that the reduction modulo $\ell$ of (a lattice in) $\rho _\pi$ is isomorphic to $\bar {\rho }_\mathfrak {m}$. Let $v$ be a place in $T$; by [Reference CarayolCar86, Theorem A] the Galois representation attached to $\pi _v$ lifts $\bar {\rho }_{\mathfrak {m}|\Gamma _{F_v}}$. As $\pi _v$ is the Jacquet–Langlands transfer of a representation of the non-split quaternion algebra over $F_v$, we deduce using § 7.1.4 that $\bar {\rho }_\mathfrak {m}$ is not generic at $v$.
Remark 7.4.4 In the above proof, we used the parabolically induced structure of the ordinary locus to deduce that $H^*(\mathcal {S}h_{U^p}(H_T)^{b^\mathrm {ord}}, {\mathbb {F}}_{\ell })_\mathfrak {m}$ is non-zero and concentrated in one degree from the analogous properties of cohomology of the Igusa variety. One could also argue computing cohomology of $\mathcal {S}h_{U^p}(H_T)^{b^\mathrm {ord}}$ via the Leray spectral sequence, and using the fact that the ordinary locus in the flag variety is a profinite set (hence, a sheaf on it with a non-zero stalk has non-zero global sections and vanishing higher cohomology).
7.5 Cohomology of quaternionic Shimura varieties
7.5.1
Let $\ell$ be a prime number. In this section, we explain how the arguments used in this paper can be extended to study the cohomology with ${\mathbb {F}}_\ell$-coefficients of quaternionic Shimura varieties attached to non-split quaternion algebras. In a nutshell, the strategy we used for Hilbert modular varieties can be applied in this generality, with the difference that we do not need to restrict to non-Eisenstein maximal ideals, as Shimura varieties attached to non-split quaternion algebras have no boundary. The construction of Galois representations is also simpler in this case, therefore some results also apply to the case $\ell = 2$.
We fix a non-split quaternion algebra $B$ over a totally real number field $F$ of degree $g$. Let $R$ (respectively, $R_\infty$) be the set of places (respectively, infinite places) of $F$ where $B$ is ramified. In this section, we will denote by $G$ the group $\mathrm {Res}_{F/{\mathbb {Q}}}B^\times$; we fix a neat compact open subgroup $K \subset G({\mathbb {A}}_f)$ and we denote by $Sh_K(G)$ the corresponding Shimura variety, of dimension $d:=g-|R_\infty |$. Let $\mathbb {T}$ be the Hecke algebra generated by operators at places of residue characteristic different from $\ell$ where $B$ is unramified and $K$ is hyperspecial. Given a prime $p$ totally split in $F$, fix an isomorphism $\bar {{\mathbb {Q}}}_p \simeq {\mathbb {C}}$, inducing a bijection between the set $\Sigma _\infty$ of infinite places and the set $\Sigma _p$ of $p$-adic places of $F$. We denote by $R_p$ the set of $p$-adic places corresponding to $R_\infty$. The cocharacter of $G_{\bar {{\mathbb {Q}}}_p}$ induced by the cocharacter coming from the Shimura datum attached to $G$ is central at places in $R_p$. In the rest of the section we will discuss the proof of the following result.
Theorem 7.5.2 Let $\ell$ be a prime number and $\mathfrak {m} \subset \mathbb {T}$ a maximal ideal in the support of $H^*(Sh_K(G), {\mathbb {F}}_\ell )$.
(i) There exists a unique Galois representation $\bar {\rho }_\mathfrak {m}: \Gamma _F \rightarrow \operatorname {GL}_2(\bar {{\mathbb {F}}}_\ell )$ attached to $\mathfrak {m}$, in the sense of Theorem 2.2.1.
(ii) Let $p\neq \ell$ be an odd prime number which splits completely in $F$ and such that $B$ is unramified at every place above $p$ and $K=K^pK_p$ with $K_p \subset G({\mathbb {Q}}_p)$ hyperspecial. Let $\delta _p(\mathfrak {m})$ be the cardinality of the set of places $v \in \Sigma _p \smallsetminus R_p$ such that $\bar {\rho }_\mathfrak {m}$ is not generic at $v$. Then
\[ i \not \in [d-\delta_p(\mathfrak{m}), d+\delta_p(\mathfrak{m})]\Rightarrow H^i(Sh_K(G), {\mathbb{F}}_\ell)_\mathfrak{m} = 0. \](iii) If $\ell >2$ and the image of $\bar {\rho }_{\mathfrak {m}}$ is not solvable, then
\[ i \neq d \Rightarrow H^i(Sh_K(G), {\mathbb{F}}_\ell)_\mathfrak{m} = 0. \]
7.5.3
Take a prime $p$ as in point (ii) of the theorem. We choose an auxiliary $CM$ extension $E/F$ such that every finite place in $R$ is inert in $E$, and a place of $F$ above $p$ is split (respectively, inert) in $E$ if it belongs (respectively, does not belong) to $R_p$. We consider the auxiliary unitary group $H_\emptyset$ constructed as in § 3.1.3; we will denote $H_\emptyset$ by $H$ for simplicity. We can write the Kottwitz set $B(H_{{\mathbb {Q}}_p}, \mu )$ as a product $B(H_{{\mathbb {Q}}_p}, \mu )=\prod _{\Sigma _p}B(H_{\mathfrak {p}}, \mu _{\mathfrak {p}})$, where $B(H_{\mathfrak {p}}, \mu _{\mathfrak {p}})$ has one element (respectively, two elements, the basic and the $\mu _\mathfrak {p}$-ordinary element) if $\mathfrak {p} \in R_p$ (respectively, if $\mathfrak {p} \in \Sigma _p \smallsetminus R_p$). We fix a compact open subgroup $K_E=(\mathcal {O}_E \otimes {\mathbb {Z}}_p)^\times K_E^{p}$ sufficiently small with respect to $K$, and we let $U\subset H({\mathbb {A}}_f)$ be the image of $K_E \times K$. Given $b=(b_\mathfrak {p})_{\mathfrak {p} \in \Sigma _p} \in B(H_{{\mathbb {Q}}_p}, \mu )$ we have the corresponding Newton stratum $\overline {Sh}^b_{U}(H)$ which is affine and smooth, of dimension $d-\varepsilon _b$, where $\varepsilon _b$ denotes the number of places $\mathfrak {p} \in \Sigma _p \smallsetminus R_p$ such that $b_\mathfrak {p}$ is basic.
Given a set $T \subset \Sigma _p \smallsetminus R_p$, let $B_T$ be the quaternion algebra over $F$ ramified at places in $R$ as well as at places in $T$ and at the corresponding infinite places. We let $G_T:=\mathrm {Res}_{F/{\mathbb {Q}}}B_T^\times$; fix an isomorphism $G({\mathbb {A}}_f^{(p)})\simeq G_T({\mathbb {A}}_f^{(p)})$, allowing us to see $K^p$ as a subgroup of $G_T({\mathbb {A}}_f^{(p)})$. The arguments in §§ 3.2 and 3.3 go through in this setting; in particular, one can define moduli problems giving rise to integral models of the Shimura varieties attached to the groups $H$ and $H_T$; this makes it possible to define Igusa varieties, and Theorem 4.2.4 has an analogue in this setting. Similarly, we have a description of the fibres of the relevant Hodge–Tate period maps in terms of Igusa varieties, and of the $\mu$-ordinary locus at infinite level as being parabolically induced from the corresponding Igusa variety.
Theorem 7.5.2 will follow from the following proposition.
Proposition 7.5.4 Take $b=(b_\mathfrak {p})_{\mathfrak {p} \in \Sigma _p} \in B(H_{{\mathbb {Q}}_p}, \mu )$ corresponding to a Newton stratum with smallest possible dimension such that $H^*(\overline {Sh}^b_{U}(H), {\mathbb {F}}_\ell )_\mathfrak {m} \neq 0$. Let $T \subset \Sigma _p \smallsetminus R_p$ be the set of places $\mathfrak {p}$ such that $b_\mathfrak {p}$ is basic. Then there is a compact open subgroup $K_{T, p}\subset G_T({\mathbb {Q}}_p)$ such that
Proof. As $H^*(\overline {Sh}^b_{U}(H), {\mathbb {F}}_\ell )_\mathfrak {m} \neq 0$ we deduce that $H^*(\mathrm {Ig}^b, {\mathbb {F}}_\ell )_\mathfrak {m} \neq 0$, hence by Theorem 4.2.4 we get $H^*(\mathrm {Ig}_T^{{\mathrm {ord}}}, {\mathbb {F}}_\ell )_\mathfrak {m} \neq 0$. Denoting by $\pi _{\mathrm {HT}}^T$ the Hodge–Tate period map for $\mathcal {S}h_{U^p}(H_T)$, we deduce as in Lemma 7.4.2 that $(R\pi _{\mathrm {HT}, *}^T {\mathbb {F}}_{\ell })_\mathfrak {m}$ is supported only on the $\mu _T$-ordinary locus. Perversity (up to shift) of $R\pi _{\mathrm {HT}, *}^T {\mathbb {F}}_{\ell }$ implies that $H^*(\mathrm {Ig}_T^{\mathrm {ord}}, {\mathbb {F}}_\ell )_\mathfrak {m}$ is non-zero only in middle degree; the same argument as in § 7.4.3 then shows that $H^*(\mathcal {S}h_{U^p}(H_T), {\mathbb {F}}_\ell )_\mathfrak {m}$ is concentrated in middle degree. We can finally descend to an appropriate finite level and apply Corollary 3.2.9 to deduce that $H^*(Sh_{K^{p}K_{T, p}}(G_T), {\mathbb {F}}_\ell )_\mathfrak {m}$ is concentrated in middle degree, hence $H^*(Sh_{K^{p}K_{T, p}}(G_T), {\mathbb {Q}}_\ell )_\mathfrak {m}\neq 0$.
7.5.5 Proof of Theorem 7.5.2
The existence of $\bar {\rho }_\mathfrak {m}$ follows combining Proposition 7.5.4, the description of the cohomology of $Sh_{K^{p}K_{T, p}}(G_T)$ with characteristic zero coefficients in terms of automorphic forms and the existence of Galois representations attached to quaternionic automorphic forms. The second point is proved adapting the argument in §§ 7.2 and 7.4.3. The third point follows from the second and from Lemma 7.1.8.
8. Compatibility with the $p$-adic local Langlands correspondence
Fix a prime $p$ throughout this section, which will play the role of the prime denoted by $\ell$ above. The aim of this section is to relate the completed homology of Hilbert modular varieties and the $p$-adic Langlands correspondence, building on [Reference Gee and NewtonGN22].
8.1 Completed homology
8.1.1
Following [Reference Gee and NewtonGN22] we work with locally symmetric spaces attached to $\operatorname {PGL}_{2, F}$ rather than $\operatorname {GL}_{2, F}$. Let $G:=\mathrm {Res}_{F/{\mathbb {Q}}}\operatorname {GL}_{2}$ and $\bar {G}:=\mathrm {Res}_{F/{\mathbb {Q}}}\operatorname {PGL}_{2}$. Given a compact open subgroup $\bar {K}\subset \bar {G}({\mathbb {A}}_f)$ we have the locally symmetric space
Fix a compact open subgroup $\bar {K}^p\bar {K}_0$ which is good in the sense of [Reference Gee and NewtonGN22, § 2.1], with $\bar {K}_0=\prod _{v \mid p}\operatorname {PGL}_2({\mathcal {O}}_{F_v})$. Consider the completed homology groups
Let $\mathbb {T}(\bar {K}^p)$ be the big Hecke algebra defined in [Reference Gee and NewtonGN22, Definition 2.1.11] (beware that our notation differs from that used there). It maps to the Hecke algebra $\mathbb {T}(\bar {K}^p\bar {K}_p, {\mathbb {Z}}/p^s{\mathbb {Z}})$ acting on homology with ${\mathbb {Z}}/p^s{\mathbb {Z}}$-coefficients of the locally symmetric space of level $\bar {K}^p\bar {K}_p$ for each $\bar {K}_p$ and each $s \geq 1$. Completed homology $\tilde {H}_*(\bar {K}^p, {\mathbb {Z}}_p)$ carries an action of $\mathbb {T}(\bar {K}^p)$ as well as of $\bar {G}({\mathbb {Q}}_p)$; we fix a maximal ideal $\mathfrak {m}\subset \mathbb {T}(\bar {K}^p)$. For $\bar {K}_p$ small enough, the ideal $\mathfrak {m}$ is the preimage of a maximal ideal in $\mathbb {T}(\bar {K}^p\bar {K}_p, {\mathbb {Z}}/p{\mathbb {Z}})$, which we will abusively denote by the same symbol (in fact any pro-$p$ group $\bar {K}_p$ does the job, cf. the proof of [Reference Gee and NewtonGN22, Lemma 2.1.14]). Hence, setting $\bar {K}=\bar {K}^p\bar {K}_p$, we have $H^*(X_{\bar {K}}(\bar {G}), {\mathbb {F}}_p)_\mathfrak {m}\simeq H_*(X_{\bar {K}}(\bar {G}), {\mathbb {F}}_p)_\mathfrak {m} \neq 0$.
8.1.2
Let us now assume that $p>3$; we take $\bar {K}$ as above, and assume in addition that it is the image of a compact open subgroup $K \subset G({\mathbb {A}}_f)$. The natural map $Sh_K(G) \rightarrow X_{\bar {K}}(\bar {G})$ is a finite étale Galois cover, hence $H^*(Sh_K(G), {\mathbb {F}}_p)_{\mathfrak {m}}\neq 0$. By Theorem 2.2.1 there is a Galois representation $\bar {\rho }_\mathfrak {m}: \Gamma _F \rightarrow \operatorname {GL}_2(\bar {{\mathbb {F}}}_p)$ attached to $\mathfrak {m}$. Let us suppose that the projective image of $\bar {\rho }_\mathfrak {m}$ contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_p)$ or is isomorphic to $A_5$; then Theorem 7.1.1 implies that, for every $K'_p\subset K_{p}$, we have
for $i< g$; the Hochschild–Serre spectral sequence attached to the Galois cover $Sh_{K^pK'_p}(G)\rightarrow X_{\overline {K^pK'_p}}(\bar {G})$ implies that the same property holds true for the cohomology of $X_{\overline {K^pK'_p}}(\bar {G})$, hence $H^*(X_{\overline {K^pK'_p}}(\bar {G}), {\mathbb {F}}_p)_\mathfrak {m}\simeq H_*(X_{\overline {K^pK'_p}}(\bar {G}), {\mathbb {F}}_p)_\mathfrak {m}$ is concentrated in degree $g$. Therefore, assumptions (a) and (b) of [Reference Gee and NewtonGN22, Proposition 4.2.1] are satisfied (note that assumption (b) trivially holds since, with the notation of [Reference Gee and NewtonGN22, Proposition 4.2.1], we have $l_0=0$ in our situation). Thanks to [Reference Gee and NewtonGN22, Proposition 4.2.1] we obtain that $\tilde {H}_i(\bar {K}^p, {\mathbb {Z}}_p)_\mathfrak {m}=0$ if $i \neq g$ and $\tilde {H}_g(\bar {K}^p, {\mathbb {Z}}_p)_\mathfrak {m}$ is a projective, $p$-torsion-free ${\mathbb {Z}}_p[[\bar {K}_{0}]]$-module. Furthermore, there is a Galois representation
lifting $\bar {\rho }_\mathfrak {m}$, as in [Reference Gee and NewtonGN22, Conjecture 3.3.3(2)]. It can be constructed as in [Reference ScholzeSch18, § 5]: the argument in [Reference ScholzeSch18, § 5], glueing representations valued in Hecke algebras at increasing finite level, can be applied in our situation as (co)homology with ${\mathbb {Z}}_p$-coefficients is concentrated in one degree and torsion-free after localisation at $\mathfrak {m}$, and cohomology with ${\mathbb {Q}}_p$-coefficients localised at $\mathfrak {m}$ is described in terms of Hilbert cusp forms.
8.2 $p$-adic local Langlands
Assume from now on that $p$ is totally split in $F$. We want to describe the relation between completed homology of Hilbert modular varieties and the $p$-adic Langlands correspondence for $\operatorname {GL}_2({\mathbb {Q}}_p)$, using the machinery of [Reference Gee and NewtonGN22]. As remarked in [Reference Gee and NewtonGN22, § 5.4], assumption (a) of [Reference Gee and NewtonGN22, Proposition 4.2.1], which we established above, is the key input needed to apply the results in [Reference Gee and NewtonGN22].
8.2.1
We first need to introduce some notation. We replace ${\mathbb {Z}}_p$ by the ring of integers ${\mathcal {O}}$ of a finite extension of ${\mathbb {Q}}_p$, with residue field $k$, so that $\bar {\rho }_\mathfrak {m}$ takes values in $\operatorname {GL}_2(k)$. Furthermore, up to further extending $\mathcal {O}$, we may, and will, assume that $k$ contains all the eigenvalues of the elements in the image of $\bar {\rho }_\mathfrak {m}$ (as in [Reference Gee and NewtonGN22, § 3.2]). We denote by $L$ the fraction field of ${\mathcal {O}}$. For a place $v \mid p$, under suitable assumptions on $\bar {\rho }_{\mathfrak {m}_{|\Gamma _{F_v}}}$ (for example, if it is absolutely irreducible) we have the universal local deformation ring $R_v^{\mathrm {def}}$ of $\bar {\rho }_{\mathfrak {m} \mid \Gamma _{F_v}}$. We denote by $\pi _v$ the $k$-representation of $\operatorname {PGL}_2(F_v)$ attached to $\bar {\rho }_{\mathfrak {m} \mid \Gamma _{F_v}}$, and we let $P_v$ be the projective envelope of $\pi _v^\vee$ in the Pontryagin dual of the category of locally admissible ${\mathcal {O}}$-representations of $\operatorname {PGL}_2(F_v)$. We set $R_p^{\mathrm {loc}}:=\hat {\otimes }_{v\mid p, {\mathcal {O}}} R_v^{\mathrm {def}}$; then $P:=\hat {\otimes }_{v \mid p, {\mathcal {O}}}P_v$ has an $R_p^{\mathrm {loc}}$-module structure, cf. [Reference PaškūnasPaš13, Proposition 6.3, Corollary 8.7] (see also [Reference Gee and NewtonGN22, § 5.1]). Finally, the representation $\rho _\mathfrak {m}$ gives rise to a map $R_{p}^{\mathrm {loc}}\rightarrow \mathbb {T}(\bar {K}^p)_\mathfrak {m}$. Let $N(\bar {\rho }_\mathfrak {m})$ be the prime-to-$p$-conductor of $\bar {\rho }_\mathfrak {m}$ and let $\bar {K}_1(N(\bar {\rho }_\mathfrak {m}))$ be the image of $\{M \in \operatorname {GL}_2(\hat {\mathcal {O}}_F)\mid M \equiv (\begin{smallmatrix}* & *\\ 0 & 1\end{smallmatrix}) \pmod {N(\bar {\rho }_\mathfrak {m})}\}$ (more precisely, if this group is not good, we make it smaller at places where $\bar {\rho }_\mathfrak {m}$ admits no ramified deformations).
Theorem 8.2.2 Let $p>3$ be a prime which splits completely in $F$. Assume that the following assertions hold true.
(i) The projective image of the Galois representation $\bar {\rho }_\mathfrak {m}$ attached to $\mathfrak {m}$ contains a conjugate of $\operatorname {PSL}_2({\mathbb {F}}_p)$ or is isomorphic to $A_5$.
(ii) If $\bar {\rho }_\mathfrak {m}$ is ramified at some place $v$ not lying above $p$, then $v$ is not a vexing prime.
(iii) For each place $v \mid p$, the restriction of $\bar {\rho }_\mathfrak {m}$ to $\Gamma _{F_v}$ is absolutely irreducible.
Then there is an isomorphism of $\mathbb {T}(\bar {K}_1(N(\bar {\rho }_\mathfrak {m}))^p)_\mathfrak {m}[\bar {G}({\mathbb {Q}}_p)]$-modules
for some $m \geq 1$.
Proof. This is [Reference Gee and NewtonGN22, Proposition 5.1.4], which follows from [Reference Gee and NewtonGN22, Conjecture 5.1.2]. Let us explain why this and other conjectures formulated in [Reference Gee and NewtonGN22] hold true in our setting, and the various assumptions made in [Reference Gee and NewtonGN22] are satisfied.
(i) In [Reference Gee and NewtonGN22, § 4.1] the authors assume that the image of restriction of $\bar {\rho }_\mathfrak {m}$ to $\Gamma _{F(\zeta _p)}$ is enormous. This is needed for the construction of Taylor–Wiles data, as in [Reference Gee and NewtonGN22, Lemma 3.3.1]. Our large image assumption and [Reference Gee and NewtonGN22, Lemma 3.2.3] imply that the group $\bar {\rho }_\mathfrak {m}(\Gamma _{F(\zeta _p)})$ is enormous if $p>5$. If $p=5$, our assumption does not guarantee that $\bar {\rho }_\mathfrak {m}(\Gamma _{F(\zeta _p)})$ is enormous. However, in this case, one can work under the assumption [Reference ScholzeSch18, Hypothesis 9.1], which originates in [Reference KisinKis09, Theorem 3.5.5] and which is satisfied in our situation. Indeed, if the image of $\mathrm {pr}\circ \bar {\rho }_\mathfrak {m}: \Gamma _F \rightarrow \operatorname {PGL}_2(\bar {{\mathbb {F}}}_5)$ is conjugate to $\operatorname {PGL}_2({\mathbb {F}}_5)$ and its kernel fixes $F(\zeta _5)$ then $[F(\zeta _5): F]=2$, which cannot happen if $p=5$ is unramified in $F$.
(ii) The assumption that $\bar {\rho }_\mathfrak {m}\neq \bar {\rho }_\mathfrak {m}\otimes \bar {\epsilon }$, where $\bar {\epsilon }$ is the mod $p$ cyclotomic character (see [Reference Gee and NewtonGN22, p. 18]) holds. Indeed because $p$ is unramified $F$, the fields $F$ and ${\mathbb {Q}}(\zeta _p)$ are linearly disjoint over ${\mathbb {Q}}$; hence $\bar {\epsilon }: \Gamma _F \rightarrow ({\mathbb {Z}}/p{\mathbb {Z}})^\times$ is surjective. In particular, there is $\gamma \in \Gamma _F$ such that $\bar {\epsilon }(\gamma )^2 \neq 1$, hence $\det \bar {\rho }_\mathfrak {m}(\gamma )\neq \det (\bar {\epsilon }\otimes \bar {\rho }_\mathfrak {m})(\gamma )$. For the same reason the first assumption in [Reference Gee and NewtonGN22, Hypothesis 4.1.3] is satisfied.
(iii) Conjecture 3.3.7 of [Reference Gee and NewtonGN22] holds: the representation denoted by $\rho _{\mathfrak {m}, Q}$ in [Reference Gee and NewtonGN22] can be constructed as explained before the statement of the theorem, and the desired local–global compatibility follows from the analogous statement for Hilbert modular forms.
(iv) The second assumption in [Reference Gee and NewtonGN22, Hypothesis 4.1.3] holds in view of the hypothesis that there are no vexing primes.
The upshot of the above discussion is that all the assumptions made at the beginning of [Reference Gee and NewtonGN22, § 5] are verified. Therefore, by [Reference Gee and NewtonGN22, Corollary 5.3.2], Conjecture 5.1.2 follows from Conjecture 5.1.12 in [Reference Gee and NewtonGN22].
It remains to justify why Conjecture 5.1.12 holds. Let $Q$ be a set of Taylor–Wiles primes and $\sigma =(\sigma _v)_{v \mid p}$ an irreducible $L$-representation of $\bar {K}_0$, with $\bar {K}_0$-stable ${\mathcal {O}}$ lattice $\sigma ^\circ$ as in [Reference Gee and NewtonGN22, p. 34]. Let $X_{\bar {K}_1(Q)}(\bar {G})$ be the space with level $\bar {K}_0$ at $p$ and $\bar {K}_1(Q)_v$ at each place $v \in Q$. We need to show that the action of $R_p^{\mathrm {loc}}$ on $H_*(X_{\bar {K}_1(Q)}(\bar {G}), \sigma ^\circ )_{\mathfrak {m}_{Q, 1}}$ factors through $R_p^{\mathrm {loc}}(\sigma )$, where the ideal $\mathfrak {m}_{Q, 1}$ is defined in [Reference Gee and NewtonGN22, Proposition 3.3.6]. Let $\mathbb {T}(\bar {K}_1(Q), \sigma )_{\mathfrak {m}_{Q, 1}}$ be the image of the Hecke algebra in the endomorphism ring of $H_g(X_{\bar {K}_1(Q)}(\bar {G}), \sigma ^\circ )_{\mathfrak {m}_{Q, 1}}$. By assumption (i) the homology $H_*(X_{\bar {K}_1(Q)}(\bar {G}), \sigma ^\circ )_{\mathfrak {m}_{Q, 1}}$ is concentrated in middle degree, and $H_g(X_{\bar {K}_1(Q)}(\bar {G}), \sigma ^\circ )_{\mathfrak {m}_{Q, 1}}$ is torsion-free; furthermore $\mathbb {T}(\bar {K}_1(Q), \sigma )_{\mathfrak {m}_{Q, 1}}$ is reduced. As in the proof of the first part of [Reference Caraiani, Emerton, Gee, Geraghty, Paškūnas and Woo ShinCEG+16, Lemma 4.17], it suffices to show that, for any $\bar {{\mathbb {Q}}}_p$-point of $\mathbb {T}(\bar {K}_1(Q), \sigma )_{\mathfrak {m}_{Q, 1}}$, the restriction to $\Gamma _{F_v}$ (for $v \mid p$) of the associated Galois representation with $\bar {{\mathbb {Q}}}_p$-coefficients is crystalline of type $\sigma _v$. The space $H_*(X_{\bar {K}_1(Q)}(\bar {G}), \sigma )_{\mathfrak {m}_{Q, 1}}$ can be described in terms of Hilbert cusp forms with algebraic weight, hence the desired result follows from local–global compatibility at places above $p$ (see [Reference KisinKis08, Theorem 4.3]). This establishes the first assertion in [Reference Gee and NewtonGN22, Conjecture 5.1.12]; the second one can be proved similarly, following the strategy in the second part of the proof of [Reference Caraiani, Emerton, Gee, Geraghty, Paškūnas and Woo ShinCEG+16, Lemma 4.17].
Remark 8.2.3 In fact, one should be able to prove a version of compatibility with the $p$-adic local Langlands correspondence without any assumptions on the tame level, for example the analogue to this setting of [Reference PanPan22b, Corollary 6.3.6]. That this would follow from Theorem A and the machinery developed by Paškūnas is more or less known to experts. We sketch the argument in this remark.
One can consider the completed cohomology of a Hilbert modular variety with ${\mathbb {Z}}_p$-coefficients. After localisation at a maximal ideal $\mathfrak {m}$ whose associated residual Galois representation is non-solvable, Theorem A implies that this is concentrated in one degree. As in [Reference PanPan22b, Corollary 6.3.6], the key point is to prove the analogue of [Reference PanPan22b, Theorem 6.3.5] that compares two actions of the local pseudo-deformation ring with fixed determinant on completed cohomology localised at $\mathfrak {m}$. (See [Reference PanPan22a, Theorem 3.5.5] for the statement in the case when there are multiple split places above $p$, which relies on [Reference PanPan22a, Corollary 3.4.12].)
The comparison of the two pseudo-deformation ring actions can be done using the method of [Reference PaškūnasPaš22, Corollary 5.6]. The key facts that would need checking are: density of those locally algebraic vectors for which the smooth part is a specific principal series representation, and semi-simplicity of the usual Hecke action on the non-Eisenstein cohomology of Hilbert modular varieties. The latter can be deduced from the Eichler–Shimura isomorphism and the existence of the Petersson inner product on Hilbert cusp forms. Density of locally algebraic vectors follows from [Reference Dospinescu, Paškūnas and SchraenDPS20, Corollary 7.8] and the fact that completed cohomology localised at $\mathfrak {m}$ with fixed central character is a direct summand of a space of continuous functions with fixed central character as in the proof of [Reference Dospinescu, Paškūnas and SchraenDPS20, Theorem 9.24]. Finally, the latter fact follows from projectivity of completed homology localised at $\mathfrak {m}$ (cf. [Reference Dospinescu, Paškūnas and SchraenDPS20, Lemma 9.16(i)]). As in § 8.1.2, to establish this last property one crucially uses Theorem A.
Acknowledgements
We are grateful to David Hansen for asking us to consider the cohomology of Hilbert modular varieties with torsion coefficients. A.C. would like to thank X. Zhu for the invitation to a 2019 AIM workshop on geometric instances of the Jacquet–Langlands correspondences, which inspired our method. We are grateful to F. Calegari, T. Gee, J. Newton, V. Paškūnas and J. Sempliner for useful conversations and correspondence, and to C. Cornut, T. Gee, J. Lourenço, S. Morra and P. Scholze for comments on a previous draft of this paper.
This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement No. 804176). A.C. was supported by a Royal Society University Research Fellowship.
Conflicts of Interest
None.