1. Introduction
Throughout this paper, $p$ is a prime number and $q$ is a power of $p$. If $X/k$ is a smooth scheme over a perfect field of characteristic $p$, then $\textbf {F-Isoc}^{{\dagger} }({X})$ denotes the category of overconvergent $F$-isocrystals on $X$ and $\textbf {F-Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$ denotes its $\overline {\mathbb {Q}}_p$-linearization. Overconvergent $F$-isocrystals are a $p$-adic analog of lisse $l$-adic sheaves.
Definition 1.1 Let $X/k$ be a smooth, geometrically connected scheme over a perfect field $k$ of characteristic $p$ and let ${{\mathcal {E}}}\in \textbf {F-Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$. We say that ${{\mathcal {E}}}$ has infinite local monodromy at infinity if, for every triple $(X',\overline {X'},f)$ where $\overline {X'}$ is smooth projective over $k$, $X'\subset \overline {X'}$ is a dense Zariski open subset, and $f\colon X'\rightarrow X$ is an alteration, the overconvergent $F$-isocrystal $f^{*}{{\mathcal {E}}}$ does not extend to an $F$-isocrystal on $\overline {X'}$.
This definition of infinite local monodromy at infinity applies equally well to lisse $\overline {\mathbb {Q}}_l$-sheaves and is compatible with the other notions of infinite local monodromy at infinity.
Theorem 1.2 Let $X/\mathbb {F}_q$ be a smooth, geometrically connected, quasi-projective scheme. Let ${{\mathcal {E}}}\in \mathbf{F\text{-}Isoc}^{{\dagger} }({X})$ be a semi-simple overconvergent $F$-isocrystal. Suppose:
• for every closed point $x$ of $X$, the polynomial $P_x({{\mathcal {E}}},t)$ has coefficients in ${{\mathbb {Q}}}\subset \mathbb {Q}_p$;
• every irreducible summand ${{\mathcal {E}}}_i\in \mathbf {F\text{-}Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$ of ${{\mathcal {E}}}$ has rank $2$, determinant $\overline {\mathbb {Q}}_p(-1)$, and infinite local monodromy around infinity.
Then ${{\mathcal {E}}}$ comes from a family of abelian varieties. More precisely, there exist a non-empty open subset $U\subset X$ and an abelian scheme $A_U\rightarrow U$, so that $\mathbb {D} (A_U[p^{\infty }])\otimes \overline {\mathbb {Q}}_p\cong \mathcal {E}|_U$.
Here, if $G\rightarrow X$ is a $p$-divisible group, $\mathbb {D}(G)$ is the (contravariant) Dieudonné crystal attached to $G$. We have the following applications. Deligne formulated what is now called the companions conjecture in [Reference DeligneDel80, Conjecture 1.2.10(vi)]. For a guide to the crystalline companions conjecture, see [Reference KedlayaKed18, Reference KedlayaKed22].
Corollary 1.3 Let $X/\mathbb {F}_q$ be a smooth, geometrically connected, quasi-projective scheme. Let $L_1$ be an irreducible rank $2$ lisse $\overline {\mathbb {Q}}_l$ sheaf on $X$ with infinite monodromy around infinity and determinant $\overline {\mathbb {Q}}_l(-1)$. Then the following are equivalent:
(1) there exist a non-empty open subset $U\subset X$ and an abelian scheme $\pi \colon A_U\rightarrow U$ such that $L_1|_U$ is a summand of $R^{1}(\pi _U)_*\overline {\mathbb {Q}}_l$;
(2) all crystalline companions to $L_1$ exist (as predicted by Deligne's crystalline companions conjecture).
Corollary 1.4 Let $X/\mathbb {F}_q$ be a smooth, geometrically connected, quasi-projective scheme. Let ${{\mathcal {E}}}_1$ be an irreducible rank $2$ object of $\mathbf {F\text{-}Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$ with infinite monodromy around infinity and determinant $\overline {\mathbb {Q}}_p(-1)$. Suppose the (number) field $E_1\subset \overline {\mathbb {Q}}_p$ generated by the coefficients of $P_x({{\mathcal {E}}}_1,t)$ as $x$ ranges through the closed points of $X$ has a single prime over $p$. Then ${{\mathcal {E}}}_1$ comes from a family of abelian varieties: there exist a non-empty open subset $U\subset X$ and an abelian scheme $A_U\rightarrow U$ such that ${{\mathcal {E}}}_1|_U$ is a summand of $\mathbb {D}(A_U[p^{\infty }])\otimes \overline {\mathbb {Q}}_p$.
In particular, Corollaries 1.3 and 1.4 provide some evidence for a question of Drinfeld [Reference DrinfeldDri12, Question 1.4] and a conjecture of the authors [Reference Krishnamoorthy and PálKP21, Conjecture 1.2]. Our motivation for formulating this conjecture was a celebrated theorem of Corlette and Simpson over $\mathbb {C}$ [Reference Corlette and SimpsonCS08, Theorem 11.2], the proof of which uses non-abelian Hodge theory. In contrast to our earlier work [Reference Krishnamoorthy and PálKP21], this paper does not use Serre–Tate deformation theory nor does it use the algebraization/globalization techniques of [Reference HartshorneHar70].
We briefly sketch the proof. Drinfeld's first work on the Langlands correspondence for $\text {GL}_2$, together with Abe's work on the $p$-adic Langlands correspondence and Lemma 2.5, implies Theorem 1.2 when $\dim (X)=1$. (The precise argument is given in Step $2$ of the proof and also uses Remark 2.8 to organize the summands, as explained in Step $1$.) Note that the resulting abelian scheme is not unique, but it is unique up to isogeny.
To deal with the higher-dimensional case, we first assume that $X$ admits a simple normal crossings compactification $\bar {X}$ and ${{\mathcal {E}}}$ is a logarithmic $F$-isocrystal with nilpotent residues. (We recall the notion of logarithmic $F$-isocrystals in Appendix A.) A technique of Katz, combined with slope bounds originally due to Lafforgue, allows one to construct a (non-canonical) logarithmic Dieudonné crystal on an open set $U$ of the compactification $\bar {X}$ whose associated logarithmic $F$-isocrystal is isomorphic to the restriction ${{\mathcal {E}}}|_U$. After the work of Kato and Trihan, this logarithmic Dieudonné crystal yields a natural line bundle, which we call the Hodge bundle $\omega$ of the logarithmic Dieudonné crystal, on $\bar {X}$.
For any odd prime $l\neq p$, let $\mathscr {A}_{h,1,l}$ denote the moduli space of principally polarized abelian schemes of dimension $h$ equipped with full level $l$ structure over $\operatorname {Spec}({{\mathbb {Z}}}[1/l])$. It is well known that the Hodge line bundle is ample on $\mathscr {A}_{h,1,l}$ over $\operatorname {Spec}({{\mathbb {Z}}}[1/l])$. We use Poonen's Bertini theorem over finite fields together with Drinfeld's result and Zarhin's trick to find a well-adapted family of extremely ample space-filling curves $\bar {C}_n$ of $\bar {X}$ that each map to the minimal compactification $\mathscr {A}^{*}_{h,1,l}\subset \mathbb {P}^{m}$ via some fixed power of the Hodge bundle $\omega |_{\bar {C}_n}^{r}$. (This step uses foundational work of Étesse, Kato, Kedlaya, and Trihan that we explain in Appendix A.) Note that $H^{0}(\bar {X},\omega ^{r})$ is a finite-dimensional vector space over a finite field and is hence a finite set. We use this finiteness together with the pigeonhole principle to prove that infinitely many of these maps can be pieced together into a rational map $\bar {X}\dashrightarrow \mathscr {A}_{h,1,l}\subset \mathbb {P}^{m}$. Therefore we obtain an abelian scheme $\psi _U\colon B_U\rightarrow U$ over some open $U\subset X$. The space-filling properties of the $\bar {C}_n$ and Zarhin's work on the Tate isogeny theorem for fields finitely generated over $\mathbb {F}_q$ then allow us to conclude.
To deduce the general case, we use Kedlaya's semi-stable reduction theorem for overconvergent $F$-isocrystals.
Remark 1.5 We comment on the relation of this paper to [Reference Krishnamoorthy and PálKP21]. In [Reference Krishnamoorthy and PálKP21] we prove a Lefschetz-style theorem for families of $\mathrm {GL}_2$-type abelian schemes over finite fields. This has the following implication for [Reference Krishnamoorthy and PálKP21, Conjecture 1.2]: if $X/\mathbb {F}_q$ is a smooth projective variety, then there exists an ample curve $C\subset X$ such that if ${{\mathcal {E}}}\in \textbf {F-Isoc}({X})_{\overline {\mathbb {Q}}_p}$ and ${{\mathcal {E}}}|_C$ comes from an abelian scheme $A_C\rightarrow C$ of $\mathrm {GL}_2$-type, then there is an open subset $U\subset X$ such that ${{\mathcal {E}}}|_U$ comes from an abelian scheme $B_U\rightarrow U$ of $\mathrm {GL}_2$-type. (It follows from Zarhin's work on the Tate isogeny conjecture that $B_C\rightarrow C$ is indeed isogenous to $A_C\rightarrow C$.) To prove this, we use Serre–Tate deformation theory and globalization results of [Reference HartshorneHar70], the latter of which critically uses the positivity of $C$ in $X$. In this paper, we only deal with non-proper varieties $X/\mathbb {F}_q$ and we use infinitely many (space-filling, affine) curves together with a result of Drinfeld, which is only known for affine curves. In particular, the main results of [Reference Krishnamoorthy and PálKP21] do not imply the main result of this paper.
2. Preliminaries
Before proving Theorem 1.2, we need several preliminary results. A key ingredient in the proof is the following theorem, which is a byproduct of Drinfeld's first work on the Langlands correspondence for $\mathrm {GL}_2$.
Theorem 2.1 (Drinfeld)
Let $C/\mathbb {F}_q$ be a smooth affine curve and let $L_1$ be a rank $2$ irreducible $\overline {\mathbb {Q}}_l$ sheaf with determinant $\overline {\mathbb {Q}}_l(-1)$. Suppose $L_1$ has infinite local monodromy around some point at $\infty \in \overline {C}\backslash C$. Then $L_1$ comes from a family of abelian varieties in the following sense. Let $E$ be the field generated by the Frobenius traces of $L_1$ and suppose $[E:{{\mathbb {Q}}}]=g$. Then there exist an abelian scheme
of dimension $g$ and an isomorphism $E\cong \textrm {End}_{C}(A)\otimes {{\mathbb {Q}}}$, realizing $A_C$ as a $\mathrm {GL}_{2}$-type abelian scheme, such that $L_1$ occurs as a summand of $R^{1}(\pi _C)_*\overline {\mathbb {Q}}_l$. Moreover, $A_{C}\rightarrow C$ is totally degenerate around $\infty$.
See [Reference Snowden and TsimermanST18, Proof of Proposition 19, Remark 20] for how to recover this result from Drinfeld's work. This amounts to combining [Reference DrinfeldDri83, Main Theorem, Remark 5] with [Reference Drinfel'dDri77, Theorem 1].
For completeness, we briefly recall the theory of companions and what is known about them. For a thorough summary about the definitions and also what is known, we refer the reader to [Reference KedlayaKed18]. Alternatively, the reader may see [Reference Krishnamoorthy and PálKP21, § 4].
Definition 2.2 Let $X/\mathbb {F}_q$ be a smooth, geometrically connected variety. Let $\lambda$ be a prime number and let $\mathcal {E}$ denote either a smooth $\overline {\mathbb {Q}}_{\lambda }$ sheaf on $X$ if $\lambda \neq p$ or an overconvergent $F$-isocrystal with coefficients in $\overline {\mathbb {Q}}_p$ if $\lambda =p$. Following Kedlaya [Reference KedlayaKed18, § 1], we call such ${{\mathcal {E}}}$ coefficient objects.
(1) Let $l\neq p$ be a prime number and let $L$ be a lisse $\overline {\mathbb {Q}}_l$-sheaf on $X$. Fix a (possibly non-continuous) field isomorphism $\iota \colon \overline {\mathbb {Q}}_{\lambda }\rightarrow \overline {\mathbb {Q}}_l$. We say that $L$ is an $\iota$-companion of $\mathcal {E}$ if, for all closed points $x\in X$, we have
\[ \iota(P_x(\mathcal{E},t))=P_x(L,t)\in \overline{\mathbb{Q}}_l[t], \]where $P_x(-,t)$ denotes the reverse characteristic polynomial at the closed point $x$.(2) Let $\mathcal {F}$ be an overconvergent $F$-isocrystal on $X$ with coefficients in $\overline {\mathbb {Q}}_p$ and fix an isomorphism $\iota \colon \overline {\mathbb {Q}}_{\lambda }\rightarrow \overline {\mathbb {Q}}_p$. We say $\mathcal {F}$ is an $\iota$-companion of $\mathcal {E}$ if, for all closed points $x\in X$, we have
\[ \iota(P_x(\mathcal{E},t))=P_x(\mathcal{F},t)\in \overline{\mathbb{Q}}_p[t]. \]
In either of these cases, we say that the $\iota$-companion to $\mathcal {E}$ exists.
Suppose $\mathcal {E}$ is semi-simple and each irreducible summand has algebraic determinant. Then Deligne's conjecture, together with Crew's $p$-adic enhancement, predict that all $\iota$-companions to ${{\mathcal {E}}}$ exist. It follows from work of Abe, Abe and Esnault, Deligne, Drinfeld, Kedlaya, and Lafforgue [Reference Abe and EsnaultAE19, Reference AbeAbe18, Reference DeligneDel12, Reference DrinfeldDri12, Reference LafforgueLaf02] that this conjecture is known to hold in the following cases.
Theorem 2.3 Let $X/\mathbb {F}_q$ be a smooth, geometrically connected variety. Let $\mathcal {E}$ be a semi-simple coefficient object on $X$ such that the irreducible summands have algebraic determinant.
• If $\dim (X)=1$, then all $\iota$-companions exist ([Reference LafforgueLaf02, Théorème VII.6] and [Reference AbeAbe18, Theorem 4.4.1]).
• For any $l\neq p$ and any isomorphism $\iota \colon \overline {\mathbb {Q}}_{\lambda }\rightarrow \overline {\mathbb {Q}}_l$, the $\iota$-companion to $\mathcal {E}$ exists ([Reference DrinfeldDri12, Theorem 1.1] and [Reference Abe and EsnaultAE19, Theorem 4.2] or [Reference KedlayaKed18, Theorem 0.4.1]).
In particular, $p$-adic companions are not known to exist when $\dim (X)>1$, although Kedlaya has recently proposed a promising strategy [Reference KedlayaKed21].
Proposition 2.4 Maintain the hypotheses of Theorem 1.2. Let $\iota \colon \overline {\mathbb {Q}}_p\rightarrow \overline {\mathbb {Q}}_l$ be a field isomorphism and let $L:=\ ^{\iota }{{\mathcal {E}}}$ be the (semi-simple) $\iota$-companion to ${{\mathcal {E}}}$.
• The isomorphism class of $L$ is independent of the choice of $\iota$.
• Let $L_i$ be an irreducible summand of $L$. Then $L_i$ has rank 2, determinant $\overline {\mathbb {Q}}_l(-1)$, and infinite monodromy at infinity.
Proof. For all closed points $x$ of $X$, we have that $P_x(L,t)\in {{\mathbb {Q}}}[t]\subset \overline {\mathbb {Q}}_l[t]$ as $\iota ({{\mathbb {Q}}})={{\mathbb {Q}}}\subset \overline {\mathbb {Q}}_l$. The first statement then follows from the Cebotarev density theorem and the Brauer–Nesbitt theorem.
If ${{\mathcal {E}}}_i$ is an irreducible summand of ${{\mathcal {E}}}$, then $^{\iota }{{\mathcal {E}}}_i$ is an irreducible $\overline {\mathbb {Q}}_l$-sheaf by [Reference KedlayaKed18, Theorem 3.3.1]. As the companions relation commutes with direct sum, it follows that if ${{\mathcal {E}}}\cong \oplus {{\mathcal {E}}}_i^{m_i}$ is the decomposition of ${{\mathcal {E}}}$ into irreducible objects in $\textbf {F-Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$, then $L\cong \oplus (^{\iota }{{\mathcal {E}}}_i)^{m_i}$ is a decomposition of $L$ into irreducible lisse $\overline {\mathbb {Q}}_l$-sheaves on $X$. One may observe that $\det (^{\iota }{{\mathcal {E}}}_i)\cong \overline {\mathbb {Q}}_l(-1)$ because, for every closed point $x$ of $X$, the constant term of $P_x({{\mathcal {E}}}_i,t)$ is $q$ and hence the constant term of $P_x(^{\iota }{{\mathcal {E}}}_i,t)$ is also $q$. Finally, suppose for contradiction that there exists an $i$ with $L_i:=\ ^{\iota }{{\mathcal {E}}}_i$ having finite local monodromy at infinity. Then there exist a smooth projective variety $\bar {X}'/\mathbb {F}_q$, an open dense subscheme $X'\subset \bar {X}'$, and an alteration $f\colon X'\rightarrow X$ such that $f^{*}L_i$ extends to $\bar {X}'$. It follows from [Reference KedlayaKed18, Corollary 3.3.3] that $f^{*}{{\mathcal {E}}}_i$ also extends to $\bar {X}'$, contradicting the hypothesis that ${{\mathcal {E}}}_i$ had infinite local monodromy at infinity.
We will need the following lemma to ensure that, given the hypotheses of Theorem 1.2, every $p$-adic companion of ${{\mathcal {E}}}_i$ is again a summand of ${{\mathcal {E}}}$; moreover, the companion relation preserves multiplicity in the isotypic decomposition of ${{\mathcal {E}}}$.
Lemma 2.5 Let $X/\mathbb {F}_q$ be a smooth, geometrically connected scheme.
(1) Let $l\neq p$ be a prime and let $L$ be a lisse, semi-simple $\overline {\mathbb {Q}}_l$-sheaf on $X$, all of whose irreducible summands $L_i$ have algebraic determinant. Suppose that, for all closed points $x$ of $X$, we have
\[ P_x(L,t)\in {{\mathbb{Q}}}[t]\subset \overline{\mathbb{Q}}_l[t]. \]Let $L_i$ be an irreducible summand of $L$ that occurs with multiplicity $m_i$ and $\iota \in \text {Aut}_{{{\mathbb {Q}}}}(\overline {\mathbb {Q}}_l)$ be a field automorphism. Then the $\iota$-companion to $L_i$, denoted $^{\iota }L_i$, is isomorphic to an irreducible summand of $L$ that occurs with multiplicity $m_i$.(2) Let ${{\mathcal {F}}}$ be a semi-simple object of $\,\mathbf {F\text{-}Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$, all of whose irreducible summands ${{\mathcal {F}}}_i$ have algebraic determinant. Suppose that, for all closed points $x$ of $X$, we have
\[ P_x({{\mathcal{F}}},t)\in {{\mathbb{Q}}}[t]\subset \overline{\mathbb{Q}}_p[t]. \]Let ${{\mathcal {F}}}_i$ be an irreducible summand of ${{\mathcal {F}}}$ that occurs with multiplicity $m_i$. Let $\iota \in \text {Aut}_{{{\mathbb {Q}}}}(\overline {\mathbb {Q}}_p)$. Then the $\iota$-companion of ${{\mathcal {F}}}_i$, denoted by $^{\iota }{{\mathcal {F}}}_i$, exists and is isomorphic to a direct summand of ${{\mathcal {F}}}$ that occurs with multiplicity $m_i$.
Proof. We reduce the crystalline case to the étale case. (Note that we could have equivalently proceeded by reduction to curves using [Reference Abe and EsnaultAE19].) As ${{\mathcal {F}}}$ is semi-simple, write an isotypic decomposition:
Note that each ${{\mathcal {F}}}_i$ is pure by [Reference Abe and EsnaultAE19, Theorem 2.7]. Fix an isomorphism $\sigma \colon \overline {\mathbb {Q}}_p\rightarrow \overline {\mathbb {Q}}_l$. By [Reference Abe and EsnaultAE19, Theorem 4.2] or [Reference KedlayaKed18, Corollary 3.5.3], the $\sigma$-companion to each ${{\mathcal {F}}}_i$ exists as an irreducible lisse $\overline {\mathbb {Q}}_l$-sheaf $L_i$. Setting $L$ to be the semi-simple $\sigma$-companion of ${{\mathcal {F}}}$, we have
Set $\iota \in \text {Aut}_{{{\mathbb {Q}}}}(\overline {\mathbb {Q}}_p)$. Then ${{\mathcal {F}}}_j$ is the $\iota$-companion to ${{\mathcal {F}}}_i$ if and only if $L_j$ is the $\sigma \circ \iota \circ \sigma ^{-1}$-companion to $L_i$. Therefore it suffices to prove the result in the étale setting.
Let $M$ be an irreducible lisse $\overline {\mathbb {Q}}_l$-sheaf on $X$. Then $M$ is pure by [Reference DeligneDel12, Théorème 1.6] and class field theory. Then the multiplicity of $M$ in the semi-simple sheaf $L$ is $\dim (H^{0}(X,M^{*}\otimes L))$. By assumption we have that, for all closed points $x$ of $X$, $P_x(L,t)\in {{\mathbb {Q}}}[t]\subset \overline {\mathbb {Q}}_l[t]$. Let $\iota \in \textrm {Aut}_{{{\mathbb {Q}}}}(\overline {\mathbb {Q}}_l)$, and note that the semi-simple $\iota$-companion to $L$ is again isomorphic to $L$. Then we claim that the $\iota$-companion to $M^{*}\otimes L$ is isomorphic to $(^{\iota } M^{*})\otimes L$. Indeed, this follows from the following two facts. First of all, both $M^{*}\otimes L$ and $(^{\iota } M^{*})\otimes L$, being the tensor product of semi-simple representations of characteristic 0, are semi-simple. Second, it follows from the fundamental theorem of symmetric functions that for fixed $d,e\in \mathbb {N}$ there exist universal polynomials $(u_i)_{i=0}^{de}$ in the ring $\mathbb {Q}[\alpha _1,\dots,\alpha _d,\beta _1,\dots,\beta _e]$ with the following property. Let $V$ and $W$ be finite-dimensional vector spaces over a field $K$ of characteristic 0 and of dimensions $d$ and $e$ and let $A$ and $B$ be linear operators on $V$ and $W$, respectively. Write $P(A,t)=\sum _{i=0}^{d}a_it^{i}$ and $P(B,t)=\sum _{j=0}^{e}b_jt^{j}$ for the reverse characteristic polynomials of $A$ and $B$. Then the reverse characteristic polynomial $P(A\otimes B,t)$ of $A\otimes B$ is equal to
Translating back, let $x$ be a closed point of $X$ and write $P_x(M^{*},t)=\sum _{i=0}^{d} a_it^{i}$ and $P_x(L,t)=\sum _{j=0}^{e} b_jt^{j}$. Then we have
It follows that
But $\iota (b_j)=b_j$ because $b_j\in \mathbb {Q}$ for all $j$. Therefore $P_x(^{\iota }(M^{*}\otimes L),t)=P_x(^{\iota }(M^{*})\otimes L,t)$. The semi-simplicity of $^{\iota }(M^{*}\otimes L)$ and $^{\iota }M^{*}\otimes L$ allows us to conclude that $^{\iota }(M^{*}\otimes L)$ is isomorphic to $^{\iota }M^{*}\otimes L$.
On the other hand, the exact argument of [Reference Abe and EsnaultAE19, 3.2] for lisse $l$-adic sheaves implies that $\dim (H^{0}(X,M^{*}\otimes L))=\dim (H^{0}(X,\ ^{\iota }(M^{*} \otimes L))$. Therefore $\dim (H^{0}(X,M^{*}\otimes L))=\dim (H^{0}(X,(^{\iota }M^{*})\otimes L))$, and the result follows.
Remark 2.6 The argument of [Reference Abe and EsnaultAE19, 3.2] cited in the proof of Lemma 2.5 is based on [Reference LafforgueLaf02, Corollary VI.3] and uses $L$-functions. A similar idea is used in the proof that the companions relations preserves irreducibility, which was crucial to Proposition 2.4. See also [Reference KedlayaKed18, Lemma 3.1.5, Theorem 3.3.1].
Remark 2.7 It follows from the argument of Lemma 2.5 that if $X/\mathbb {F}_q$ is smooth and geometrically connected and if ${{\mathcal {E}}}, {{\mathcal {F}}}\in \textbf {F-Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$ are semi-simple objects, all of whose summands are algebraic, then, for any field isomorphism $\iota \colon \overline {\mathbb {Q}}_p\rightarrow \overline {\mathbb {Q}}_l$, we have $^{\iota }({{\mathcal {E}}}\otimes {{\mathcal {F}}})\cong \ ^{\iota }{{\mathcal {E}}}\otimes \ ^{\iota }{{\mathcal {F}}}$, that is, the relation of being $\iota$-companions commutes with tensor product.
Remark 2.8 It follows from Lemma 2.5 that, in the context of Theorem 2.1, there is a decomposition
where the $L_i$ form a complete set of $\overline {\mathbb {Q}}_l$ companions. There are exactly $g$ non-isomorphic companions because the field generated by Frobenius traces of $L_1$ is isomorphic to $E$ and the $l$-adic companions are in bijective correspondence with the embeddings $E\hookrightarrow \overline {\mathbb {Q}}_l$. In particular, each companion occurs with multiplicity 1. In fact, as $E\cong \text {End}_C(A_C)\otimes {{\mathbb {Q}}}$, it follows that $E\otimes \overline {\mathbb {Q}}_l$ acts on $R^{1}(\pi _C)_*\overline {\mathbb {Q}}_l$. On the other hand, $E\otimes \overline {\mathbb {Q}}_l\cong \prod _{i} \overline {\mathbb {Q}}_l$, where $i$ runs over the embeddings $E\hookrightarrow \overline {\mathbb {Q}}_l$. For each $i$, pick a non-trivial idempotent $e_i\in E\otimes \overline {\mathbb {Q}}_l$ whose image is the $i$th component of the direct product decomposition. The above direct sum decomposition is induced by these $e_i$.
To apply Drinfeld's Theorem 2.1, we will use the following lemma.
Lemma 2.9 Let $Y/\mathbb {F}_q$ be a smooth, geometrically connected, projective scheme and let $\alpha$ be a line bundle on $Y$. Let $M\subset \mathbb {P}^{m}_{\mathbb {F}_q}$ be a closed subset. Suppose there exists an infinite collection $(C_n)_{n\in \mathbb {N}}$ of smooth, projective, geometrically connected, closed subcurves $C_n\subset Y$ such that:
(1) for each $n\in \mathbb {N}$, the natural map $H^{0}(Y,\alpha )\rightarrow H^{0}(C_n,\alpha |_{C_n})$ is an isomorphism;
(2) for any infinite subset $S\subset \mathbb {N}$, the union
\[ \displaystyle \bigcup_{n\in S}C_n \]is Zariski dense in $Y$;(3) for each curve $C_n$, there exist $m+1$ globally generating sections
\[ t_{n,0},\dots,t_{n,m}\in H^{0}(C_n,\alpha|_{C_n}) \]such that the induced morphism to $\mathbb {P}^{m}$ factors through $M$:
Then there exist global sections $\tilde {t}_0,\dots,\tilde {t}_m\in H^{0}(Y,\alpha )$ such that the induced rational map $\tilde {f}\colon Y\dashrightarrow \mathbb {P}^{m}$ has image in $M$. Moreover, $\tilde {f}$ can be chosen to be compatible with infinitely many of the maps $f_n$.
Proof. There are finitely many ordered $m+1$-tuples of sections $H^{0}(Y,\alpha )\cong H^{0}(C_n,\alpha |_{C_n})$ because $H^{0}(Y,\alpha )$ is a finite-dimensional vector space over $\mathbb {F}_q$. By the pigeonhole principle, in our infinite collection we may find an $m+1$-tuple of sections $\tilde {t}_0,\dots,\tilde {t}_m\in H^{0}(Y,\alpha )$ such that there exists an infinite set $S\subset \mathbb {N}$ with
for every $n\in S$. There is therefore an induced rational map $\tilde {f}\colon Y\dashrightarrow \mathbb {P}^{m}$ with $\tilde {f}|_{C_n}=f_n$ for each $n\in S$. On the other hand, the collection $(C_n)_{n\in S}$ is Zariski dense in $Y$ by assumption and $\tilde {f}(C_n)\subset M$; therefore the image of $\tilde {f}$ lands inside of $M$, as desired.
Lemma 2.9 has two key ingredients. The first ingredient is that if $X/\mathbb {F}_q$ is a projective variety and $\alpha$ is a coherent sheaf on $X$, then $H^{0}(X,\alpha )$ is a finite set. The second ingredient is the pigeonhole principle. To use Lemma 2.9, the following definition will be useful.
Definition 2.10 Let $\bar {X}/k$ be a smooth, geometrically connected, projective scheme of dimension at least 2, let $Z\subset \bar {X}$ be a reduced simple normal crossings divisor, and set $X:=X\backslash Z$. Let $\bar {U}\subset \bar {X}$ be an open subset whose complement has codimension at least 2. Let $(x_j)_{j=1}^{s}$ be a finite collection of closed points of $U:=\bar {U}\cap X$. Let $\alpha$ be a line bundle on $\bar {X}$. We say that $\bar {C}\subset \bar {U}$ is a good curve for the quintuple $(\bar {X}, X, \bar {U}, \alpha, (x_j)^{s}_{j=1})$ if:
• $\bar {C}$ is the smooth complete intersection of smooth ample divisors of $\bar {X}$ that intersect $Z$ in good position;
• $\bar {C}$ contains each of the closed points $x_j$, for $j=1,\dots, s$;
• the natural map $H^{0}(\bar {X},\alpha )\rightarrow H^{0}(\bar {C},\alpha |_{\bar {C}})$ is an isomorphism.
In the proof of Theorem 1.2, we will need to know that good curves exist. This is guaranteed by the following two results.
Proposition 2.11 Let $Y/k$ be a smooth, geometrically connected, projective scheme of dimension $d\geq 2$ and let $\alpha$ be a line bundle on $Y$. Let $D\subset Y$ be an ample divisor. Then there exists an $s_0>0$ such that, for any $s\geq s_0$, and for any integral divisor $E\in |sD|$ in the linear series, the natural map
is an isomorphism.
Proof. For any $s>0$, let $E\in |sD|$ be an integral divisor in the linear series. Then there is an exact sequence
If $h^{0}(Y,\alpha (-E))=h^{1}(Y,\alpha (-E))=0$, then by the long exact sequence in cohomology, the restriction map $H^{0}(Y,\alpha )\rightarrow H^{0}(E,\alpha |_E)$ is an isomorphism. Our task is therefore to show that, for all sufficiently large $s$, $h^{0}(Y,\alpha (-sD))=h^{1}(Y,\alpha (-sD))=0$.
Let $\mathfrak {L}$ be the canonical bundle of $Y$. Then by Serre duality, $h^{i}(Y,\alpha (-sD))=h^{d-i}(Y,\alpha ^{\vee }(sD)\otimes \mathfrak {L})$. It follows from Serre vanishing that there exists an $s_0>0$ such that, for any $s\geq s_0$ and for any $i< d$, $h^{d-i}(Y,\alpha ^{\vee }(sD)\otimes \mathfrak {L})=0$. Therefore, for any $s\geq s_0$ and for any $i< d$, $h^{i}(Y,\alpha (-sD))=0$ and the result follows.
Lemma 2.12 Let $\bar {X}/\mathbb {F}_q$ be a smooth, geometrically connected, projective scheme of dimension at least $2$, let $Z\subset \bar {X}$ be a reduced simple normal crossings divisor, and set $X:=\bar {X}\backslash Z$. Let $\bar {U}\subset \bar {X}$ be an open subset whose complement has codimension at least $2$. Let $(x_j)_{j=1}^{s}$ be a finite collection of closed points of $U:=\bar {U}\cap X$. Let $\alpha$ be a line bundle on $\bar {X}$. Then there is a good curve $\bar {C}\subset \bar {U}$ for the quintuple $(\bar {X}, X, \bar {U}, \alpha, (x_j)^{s}_{j=1})$
Proof. By induction, it suffices to construct a smooth ample divisor $\bar {D}\subset \bar {X}$ such that:
• $\bar {D}\cap \bar {U}$ has complementary codimension at least $2$ in $\bar {D}$;
• $\bar {D}$ intersects $Z$ transversely;
• $\bar {D}$ contains $x_j$, for $j=1,\dots, s$; and
• the natural map $H^{0}(\bar {X},\alpha )\rightarrow H^{0}(\bar {D},\alpha |_{\bar {D}})$ is an isomorphism.
This is a standard application of Poonen's Bertini theorem over finite fields [Reference PoonenPoo04, Theorem 1.3]. Fix a closed embedding $\bar {X}\hookrightarrow \mathbb {P}^{m}_{\mathbb {F}_q}$ and let $S_{\text {homog}}$ be the set of homogenous polynomials on $\mathbb {P}^{m}_{\mathbb {F}_q}$, as in [Reference PoonenPoo04, p. 1100]. Consider the set $\mathcal {T}$ of those functions $f\in S_{\text {homog}}$ such that $\bar {D}:=V(f)\cap \bar {X}$ is a smooth ample divisor of $\bar {X}$ and the above four properties hold for $\bar {D}$. Our goal is to show that $\mathcal {T}$ is non-empty.
• Let $\bar E:=\bar {X}{\setminus} \bar {U}$; by hypothesis, $\dim (\bar E)\leq n-2$. If $f\in S_{\text {homog}}$ is such that $V(f)$ does not contain any component of $\bar E$, then $\dim (V(f)\cap \bar E)\leq n-3$. For this to hold, it is sufficient that $V(f)$ avoids at least one given closed point $e_i$ on each connected component of $\bar E$.
• Write $Z=\bigcup ^{r}_{j=1} Z_j$ to be the decomposition of $Z$ into connected components. For each $J\subset \{1,2,\dots,r\}$, set $Z_J:=\bigcap _{j\in J}Z_j$ to be the corresponding scheme-theoretic intersection. By assumption, for each $J$, $Z_J$ is a smooth subvariety of $\bar {X}$. The condition that $\bar {D}$ intersects $Z$ in good position means that $\bar {D}$ must intersect each stratum $Z_J$ transversely, that is, that $Z_J\cap \bar {D}$ is a smooth subvariety of $\bar {D}$ of dimension $n-1-|J|$.
Then the positive density (and hence non-emptiness) of $\mathcal {T}$ immediately follows from [Reference PoonenPoo04, Theorem 1.3]: the conditions on $f$ are that $V(f)\cap \bar {X}$ intersect a finite set of smooth subvarieties transversely, avoid a given finite set of points, pass through another given finite set of points, and have sufficiently high degree by Proposition 2.11.
Note that Lemma 2.12 also holds with $\mathbb {F}_q$ replaced by any infinite field $k$ by the usual Bertini theorems. Finally, the following lemma is surely well known but we could not find a reference for exactly the statement we need. (The essential content is contained in [Reference Chai, Conrad and OortCCO14, § 3.3].) We will use this lemma to make a particular choice of $A_C\rightarrow C$ in the isogeny class from Drinfeld's Theorem 2.1 (though this choice will not be unique).
Lemma 2.13 Let $X$ be a scheme and let $A\rightarrow X$ be an abelian scheme. Let $r$ be a prime and let $G$ be an $r$-divisible group on $X$. Suppose there exists an isogeny $\psi \colon A[r^{\infty }]\rightarrow G$ of $r$-divisible groups on $X$ (as in [Reference Chai, Conrad and OortCCO14, 3.3.5]). Then there exist an $r$-primary isogeny $\varphi \colon A\rightarrow B$ of abelian schemes over $X$ and an isomorphism $\varepsilon \colon B[r^{\infty }]\rightarrow G$ such that the following diagram commutes:
Proof. Set $N=\text {ker}(\psi )$. Then $N$ is a (commutative) finite flat group scheme over $X$ of $r$-primary order. We have a short exact sequence in the category of fppf sheaves:
Consider the quotient $A/N$ in the category of fppf sheaves. It follows from, for example, [Reference Chai, Conrad and OortCCO14, 1.4.1.3, 1.4.1.4] that there exists an abelian scheme $B\rightarrow X$ that represents the sheaf $A/N$. We then have the following commutative diagram of fppf sheaves:
where the right vertical arrow exists because $G=\text {coker}(N\rightarrow A[r^{\infty }])$. We claim that the induced map $G\rightarrow B$ yields an isomorphism $G\rightarrow B[r^{\infty }]$. By the snake lemma, $G\rightarrow B$ is injective. However, an injective isogeny of $r$-divisible groups is an isomorphism.
3. Proofs of Theorem 1.2 and Corollaries 1.3, 1.4
Proof of Theorem 1.2 We proceed in several steps.
Step 1: organizing the summands of $\mathcal {E}$. As ${{\mathcal {E}}}_i$ is irreducible, has determinant $\overline {\mathbb {Q}}_p(-1)$, and has rank $2$, the slopes of $({{\mathcal {E}}}_i)_x$ are in the interval $[0,1]$ for every closed point $x$ of $X$ (see [Reference Drinfeld and KedlayaDK17, § 1.2, pp. 136–137], where it is deduced from Corollary 1.1.7).
Write the isotypic decomposition of ${{\mathcal {E}}}$ in $\textbf {F-Isoc}^{{\dagger} }({X})_{\overline {\mathbb {Q}}_p}$:
The field generated by the coefficients of $P_x({{\mathcal {E}}},t)$ as $x$ ranges through closed points of $X$ is ${{\mathbb {Q}}}$. Therefore, by [Reference DrinfeldDri18, E.10] and either [Reference Abe and EsnaultAE19, Theorem 4.2] or [Reference KedlayaKed18, Corollary 3.5.3], we can pick an $l$ and a field isomorphism $\sigma \colon \overline {\mathbb {Q}}_p\rightarrow \overline {\mathbb {Q}}_l$ such that the semi-simple $\sigma$ companion $L$ to ${{\mathcal {E}}}$ exists and in fact may be defined over $\mathbb {Q}_l$, that is, corresponds to a representation
(We emphasize that $L$ is independent of the choice of $\sigma$ by Proposition 2.4.) By compactness of $\pi _1(X)$, we may conjugate the representation into $\mathrm {GL}_N({{\mathbb {Z}}}_l)$. We refer to the attached lisse ${{\mathbb {Z}}}_l$-sheaf as $\tilde {L}$. Similarly, for each $i$ we denote by $L_i$ the $\sigma$-companion to ${{\mathcal {E}}}_i$ (the $L_i$ indeed do depend on the choice of $\sigma$). The companion relation commutes with direct sum; hence, we have
(See also the proof of Proposition 2.4.) Let $E_i\subset \overline {\mathbb {Q}}_p$ denote the (number) field generated by the coefficients of $P_x({{\mathcal {E}}}_i,t)$ as $x$ ranges through the closed points of $X$. Note that for each ${{\mathcal {E}}}_i$, all $p$-adic companions exist and are summands of ${{\mathcal {E}}}$ by Lemma 2.5. For each ${{\mathcal {E}}}_i$, set ${{\mathcal {F}}}_i$ to be the sum of all distinct $p$-adic companions of ${{\mathcal {E}}}_i$. Note that there are $[E_i\colon {{\mathbb {Q}}}]$ distinct $p$-adic companions of ${{\mathcal {E}}}_i$, parametrized by the embeddings $E_i\hookrightarrow \overline {\mathbb {Q}}_p$. By reordering the indices, we write the decomposition of ${{\mathcal {E}}}$ as
for some integer $1\leq b\leq a$. (Under this reordering, the collection of $({{\mathcal {E}}}_i)_{i=1}^{b}$ are all mutually not companions and, for each $b+1\leq j \leq a$, there exists a unique $1\leq i\leq b$ such that ${{\mathcal {E}}}_j$ is a companion of ${{\mathcal {E}}}_i$.) Set
Step 2: the proof in a simplified situation. We first assume that $X$ admits a simple normal crossings compactification $\bar {X}$ such that ${{\mathcal {E}}}$ extends to a logarithmic $F$-isocrystal $\bar {{\mathcal {E}}}$ with nilpotent residues on $\bar {X}$ and, moreover, that $\tilde {L}$ has trivial residual representation. Write $Z:=\bar {X}\backslash X$ for the boundary. (Note that under the above assumption on ${{\mathcal {E}}}$, the $l$-companion $L$ is tamely ramified.)
By Lemma A.7, there exist a Zariski open $\bar {U}\subset \bar {X}$ with complementary codimension at least 2, and a logarithmic Dieudonné crystal $(M_{\bar {U}},F,V)$ on $\bar {U}$ (with the logarithmic structure coming from $Z\cap \bar {U}$) such that the associated logarithmic $F$-isocrystal is isomorphic to $\overline {{{\mathcal {E}}}}|_{\bar {U}}$. (In other words, $M_{\bar {U}}$ is an $F$ and $p\circ F^{-1}$ stable lattice in $\overline {{{\mathcal {E}}}}|_{\bar {U}}$.) Let
where the $t$ denotes the dual logarithmic Dieudonné crystal. We also consider this logarithmic Dieudonné crystal as we will need to use Zarhin's trick. We set $U:=\bar {U}\backslash (\bar {U}\cap Z)$.
After Remark A.8, it follows that we may define Hodge line bundles $\omega _M$ and $\omega _N$ on $\bar {U}$ attached to the two logarithmic Dieudonné crystals. As $\bar {U}\subset \bar {X}$ has complementary codimension at least $2$ and $\bar {X}$ is smooth, it follows that $\omega _M$ and $\omega _N$ extend canonically to line bundles on all of $\bar {X}$.
The Hodge line bundle $\alpha$ on the fine moduli scheme $\mathscr {A}_{8g,1,l}\otimes \mathbb {F}_q$ is ample by [Reference Moret-BaillyMB85, Ch. IX, Théorème 3.1, p. 210] or [Reference Faltings and ChaiFC90, Ch. V, Theorem 2.5(i)]. Let $g$ be as in (3.2) and choose an $r$ so that the $\alpha ^{r}$ is very ample on $\mathscr {A}_{8g,1,l}$. As $8g>1$, it follows from the Koecher principle that $H^{0}(\mathscr {A}_{8g,1,l}\otimes \mathbb {F}_q,\alpha ^{r})$ is a finite-dimensional $\mathbb {F}_q$-vector space for all $r\in \mathbb {Z}$ [Reference Faltings and ChaiFC90, Ch. V, Theorem 1.5(ii)]. Fix a basis $s_0,\dots,s_m$ of the vector space
once and for all. There is an induced embedding $\mathscr {A}_{8g,1,l}\subset \mathbb {P}^{m}$. As is customary, denote by $\mathscr {A}^{*}_{8g,1,l}$ the Zariski closure of $\mathscr {A}_{8g,1,l}$ in $\mathbb {P}^{m}$; we call this the minimal compactification. In an abuse of notation, we also denote by $\alpha$ the Hodge line bundle on $\mathscr {A}^{*}_{8g,1,l}$. The Koecher principle implies that $H^{0}(\mathscr {A}_{8g,1,l}\otimes \mathbb {F}_q,\alpha ^{r})=H^{0}(\mathscr {A}^{*}_{8g,1,l}\otimes \mathbb {F}_q,\alpha ^{r})$; this follows from [Reference Faltings and ChaiFC90, Ch. V, Theorem 1.5(ii), Theorem 2.5(iii)].
It follows from [Reference DeligneDel12, Proposition 3.4] that there exist a finite number of closed points $(x_j)^{s}_{j=1}$ of $U$ such that, for each ${{\mathcal {E}}}_i$, the field generated by the coefficients of $P_{x_j}({{\mathcal {E}}}_i,t)\in \overline {\mathbb {Q}}_p[t]$ as $j=1,\dots, s$ is $E_i\subset \overline {\mathbb {Q}}_p$. We call this fact $\blacklozenge$.
If $\bar {C}\subset \bar {U}$ is a good curve for the quintuple $(\bar {X}, X, \bar {U}, \omega _N^{r}, (x_j)^{s}_{j=1})$ as in Definition 2.10, set $C:=\bar {C}\cap X$. Then the following three properties hold.
• Each ${{\mathcal {E}}}_i|_C$ is irreducible by [Reference Abe and EsnaultAE19, Theorem 2.6].
• The field generated by Frobenius traces of ${{\mathcal {E}}}_i|_C$ is $E_i$ by $\blacklozenge$.
• Each ${{\mathcal {E}}}_i|_C$ has infinite monodromy around $\infty$. Indeed, from the positivity of $\bar {C}$, and the good position assumption, it follows that $\bar {C}$ intersects each irreducible component $Z_m$ of $Z$ in a non-empty and transverse way; moreover, $\bar {C}$ does not intersect the codimension $2$ strata $Z_{m}\cap Z_n$. By assumption, for each ${{\mathcal {E}}}_i$, there exists a component $Z_m$ around which the monodromy around $Z_m$ of ${{\mathcal {E}}}_i$ (equivalently, of $L_i$) is infinite. On the other hand, there is a surjective morphism of tame fundamental groups
\[ \pi_1^{\text{tame}}(C)\twoheadrightarrow \pi_1^{\text{tame}}(X) \]by [Reference Esnault and KindlerEK16, Theorem 1.1(a)]. Moreover, for each $m$, we may restrict the above surjection to a surjective map of tame inertia groups\[ I_{Z_m\cap \bar{C}}^{\text{tame}}(C)\twoheadrightarrow I_{Z_m}^{\text{tame}}(X) \]around $Z_m\cap \bar {C}$ and $Z_m$, respectively. By the assumption that $L_i$ had infinite monodromy around $Z_m$ and the fact that wild inertia is a pro-$p$ group, it follows that the image of $I_{Z_m}^{\text {tame}}(X)$ in the $l$-adic representation corresponding to $L_i$ is infinite. Therefore, the image of $I_{Z_m\cap \bar {C}}^{\text {tame}}(C)$ in the $l$-adic representation corresponding to $L_i|_C$ is also infinite, or equivalently, ${{\mathcal {E}}}_i|_C$ has infinite monodromy around $Z_m\cap \bar {C}$, as desired.
Let $\bar {C}\subset \bar {U}$ be a good curve for the quintuple $(\bar {X}, X, \bar {U}, \omega _N^{r}, (x_j)^{s}_{j=1})$. Recall the decomposition from (3.1): $\displaystyle {{\mathcal {E}}}\cong \oplus _{i=1}^{b} {{\mathcal {F}}}_i^{m_i}$, where each ${{\mathcal {F}}}_i$ is the sum of the distinct companions of ${{\mathcal {E}}}_i$ under the reordering specified in Step 1. (Note that ${{\mathcal {F}}}_i$ has Frobenius traces in ${{\mathbb {Q}}}$.) By Theorem 2.1 and Remark 2.8, for each $i\in \{1,\dots,b\}$, there exists an abelian scheme $A_i\rightarrow C$ of dimension $g_i=[E_i:{{\mathbb {Q}}}]$ such that ${{\mathcal {F}}}_i|_C$ is compatible with $A_i$. By taking the iterated fiber product over $C$, it therefore follows from (3.2) that there exists an abelian scheme $\pi _C\colon A_C\rightarrow C$ of relative dimension $g$ such that
As $l$ is prime to $p$, it follows from the Galois correspondence for $\pi _1(X)$ that the category of (necessarily étale) $l$-divisible groups on $X$ is equivalent to the category of lisse $\mathbb {Z}_l$ sheaves on $X$ (see, for example, [Reference Chai, Conrad and OortCCO14, pp. 147–148], where they explain that the functor is explicitly given as the Tate $l$-group). Write $\Phi$ for an inverse functor. We have assumed that the ${{\mathbb {Z}}}_l$-lattice $\tilde {L}$ has trivial residual representation, that is, the following map is trivial:
Then it follows from the Galois correspondence that $\Phi (\tilde {L})[l]$ is isomorphic to the split étale group scheme $({{\mathbb {Z}}}/l{{\mathbb {Z}}})^{2g}$ (see, for example, the explicit formula on [Reference Chai, Conrad and OortCCO14, p. 148]). On the other hand, $\Phi (\tilde {L})$ is isogenous to $A_C[l^{\infty }]$ because $\tilde {L}$ is isogenous to $T_l(A_C)$. It follows from Lemma 2.13 that there exists an $l$-primary isogeny $A_C\rightarrow A'_C$ over $C$ such that $A'_C[l]\rightarrow C$ is isomorphic to the split étale group scheme $({{\mathbb {Z}}}/l{{\mathbb {Z}}})^{2g}$. The abelian scheme $A'_C\rightarrow C$ therefore has a full collection of $l$-torsion sections, that is, it has trivial $l$-torsion. Replacing $A_C$ by $A_C'$, we may assume that $A_C$ has trivial $l$-torsion.
Similarly, we claim that $\mathbb {D}(A_C[p^{\infty }])\otimes \overline {\mathbb {Q}}_p\cong {{\mathcal {E}}}|_C$. Indeed, $\mathbb {D}(A_C[p^{\infty }])\otimes \overline {\mathbb {Q}}_p$ is a semi-simple object of $\textbf {F-Isoc}^{{\dagger} }({C})_{\overline {\mathbb {Q}}_p}$ by [Reference PálPál15] and is compatible with $L|_C$ by [Reference Katz and MessingKM74]. Therefore, $\mathbb {D}(A_C[p^{\infty }])$ is isogenous to $(M,F,V)_C$ as Dieudonné crystals on $C$. We claim that we may replace $A_C$ by an ($p$-primarily) isogenous abelian scheme in order to ensure that
as Dieudonné crystals on $C$. To see this, use [Reference de JongdJ95] to construct a $p$-divisible group $G_C$ on $C$ where $\mathbb {D}(G_C)\cong (M_C,F,V)$. It follows that $A_C[p^{\infty }]$ and $G_C$ are isogenous. Applying Lemma 2.13, we see that there is a $p$-primary isogeny $A_C\rightarrow A'_C$ such that $A'_C[p^{\infty }]\cong G_C$. As the group of $l$-torsion points of an abelian scheme is a finite flat $l$-primary group scheme, it follows that $A'_C$ also has trivial $l$-torsion. Replace $A_C$ by $A'_C$. We emphasize that this choice of $A_C$ is not canonical!
By construction, the $l$-torsion of $A_C\rightarrow C$ is trivial; it follows that $A_C\rightarrow C$ has semi-stable reduction along $\bar {C}\cap Z$. (Use that the monodromy representation $\pi _1(C)\rightarrow \mathrm {GL}_{2g}(\mathbb {Z}_l)$ has image in $\Gamma (l):=\{1+M\,|\ M\in lM_{n\times n}(\mathbb {Z}_l)\}\subset \mathrm {GL}_{2g}(\mathbb {Z}_l)$, and the fact that if $l>2$, the group $(1+l\overline {\mathbb {Z}}_l)^{\times }$ is torsion-free. Therefore, if $\gamma \in \pi _1(C)$ has quasi-unipotent image in the representation, it then in fact has unipotent image. The claim then follows from Grothendieck's semi-stable reduction theorem for abelian varieties.)
Let $A_{\bar {C}}\rightarrow \bar {C}$ be the Néron model and let $A^{o}_{\bar {C}}\rightarrow \bar {C}$ denote the associated semi-abelian scheme, that is, the open subset of $A_{\bar {C}}\rightarrow C$ obtained by removing the non-identity components along $\bar {C}{\setminus} C$. It follows from the third part of Proposition A.11 that the logarithmic Dieudonné crystal of $A_{\bar {C}}\rightarrow \bar {C}$ constructed in Remark A.9 is isomorphic to $(M,F,V)_{\bar {C}}$. Then, by the second part of Proposition A.11, the Hodge bundle of the $A^{o}_{\bar {C}}\rightarrow \bar {C}$ is isomorphic to $\omega _M|_{\bar {C}}$.
Set $B_C:=(A_C\times _C A^{t}_C)^{4}$. By Zarhin's trick [Reference Moret-BaillyMB85, Chapitre IX, Lemme 1.1, p. 205], $B_C$ admits a principal polarization. By construction, we have that
• $B_C$ has trivial $l$-torsion, and
• $\mathbb {D}(B_C[p^{\infty }])\cong (N_C,F,V)$.
By the uniqueness part of Proposition A.11 it follows that there is an isomorphism of logarithmic Dieudonné crystals:
Hence, the Hodge line bundle of $B^{o}_{\bar {C}}\rightarrow \bar {C}$ is isomorphic to $\omega _N|_{\bar {C}}$ again by Proposition A.11. However, we emphasize again that the choice $B_C\rightarrow C$ is not canonical!
We have an induced morphism to a fine moduli scheme $C\rightarrow \mathscr {A}_{8g,1,l}$. This extends to a morphism from $\bar{C}$ to the minimal compactification $\mathscr {A}_{8g,1,l}^{*}/\mathbb {F}_q$ because the latter is proper and the former is a smooth curve:
We now claim the pullback of $\alpha$, the Hodge line bundle on $\mathscr {A}^{*}_{8g,1,l}$, is isomorphic to $\omega _N|_{\bar {C}}$. Here is the reason. Choose a toroidal compactification $\bar {\mathscr {A}}_{8g,1,l}$. We then have a commutative diagram
again, because $\bar {\mathscr {A}}_{8g,1,l}/\mathbb {F}_q$ is proper and $\bar {C}/\mathbb {F}_q$ is a smooth curve. By [Reference Faltings and ChaiFC90, Ch. V, Theorem 2.5], there is a semi-abelian scheme $G\rightarrow \bar {\mathscr {A}}_{8g,1,l}$ such that $\varphi ^{*}\alpha$ is isomorphic to the Hodge line bundle of $G\rightarrow \bar {\mathscr {A}}_{8g,1,l}$. Now, [Reference Faltings and ChaiFC90, Ch. I, Proposition 2.7] implies that $h^{*}G$ is isomorphic to $A^{o}_{\bar {C}}\rightarrow \bar {C}$, that is, the semi-abelian scheme given by the open subset of $A_{\bar {C}}\rightarrow \bar {C}$ obtained by removing the non-identity components along $\bar {C}\backslash C$. In particular, it follows from part (2) of Proposition A.11 that the Hodge line bundle of $h^{*}G$ is compatible with the Hodge line bundle constructed in Remark A.8.
In (3.3), we have already fixed a basis of sections
after pulling back the sections to $\bar {C}$ via (3.4), we obtain an $m+1$-tuple of sections $t_0,\dots,t_m$ in $H^{0}(\bar {C},\omega ^{r}_N|_{\bar {C}})$ that define the morphism $\bar {C}\rightarrow \mathscr {A}^{*}_{8g,1,l}\subset \mathbb {P}^{m}$.
In conclusion, for every good curve $\bar {C}\subset \bar {U}$ for the quintuple $(\bar {X}, X, \bar {U}, \omega _N^{r},(x_j)^{s}_{j=1})$, we have constructed an $m+1$-tuple of globally generating sections $t_0,\dots,t_m\in H^{0}(\bar {C},\omega ^{r}_N|_{\bar {C}})$ such that
• the induced map lands in $\mathscr {A}^{*}_{8g,1,l}\subset \mathbb {P}^{m}$;
• the image of $C$ under the induced map lands in $\mathscr {A}_{8g,1,l}\subset \mathscr {A}_{8g,1,l}^{*}$;
• and such that the induced abelian variety on $B_C\rightarrow C$ is isomorphic to $(A_C\times _C A_C^{t})^{4}$ where $A_C\rightarrow C$ is an abelian scheme with $\mathbb {D}(A_C[p^{\infty }])\cong (M,F,V)|_C$ as Dieudonné crystals on $C$. (Therefore we also have that $\mathbb {D}(B_C[p^{\infty }])\cong (N,F,V)|_C$.)
In particular, setting $M=\mathscr {A}_{8g,1,l}^{*}\subset \mathbb {P}^{m}$, condition (3) of Lemma 2.9 holds for $\bar {C}\subset \bar {X}$ (corresponding to the symbols $C\subset Y$ in Lemma 2.9). Note that for two such good curves $C$ and $C'$, there is no reason that the induced maps to $\mathscr {A}_{8g,1,l}$ match up on the intersection $C\cap C'$ because our choices of abelian schemes were not canonical.
For each $n>0$, let $P_n$ denote the union of the set of closed points of $U$ whose residue field is contained in $\mathbb {F}_{q^{n!}}$. Note that, for any infinite subset $S\subset \mathbb {N}$, the set $\bigcup _{n\in S}P_n$ is Zariski dense in $X$; indeed, any given closed point $x$ of $U$ is an element of $P_n$ for all $n\gg 0$. By Lemma 2.12, it follows that, for each $n>0$, there exists a good curve $\bar {C}_n\subset \bar {U}$ for the quintuple $(\bar {X}, X, \bar {U}, \omega _N^{r}, P_n)$.
For each $n\in \mathbb {N}$, by the above remarks we obtain an $m+1$-tuple of globally generating sections
such that the induced map factors $f_n\colon \bar {C}_n\rightarrow \mathscr {A}^{*}_{8g,1,l}\subset \mathbb {P}^{m}$. Moreover, any infinite subcollection of the $\bar {C}_n$ is Zariski dense because they are space-filling: if $x$ is a closed point of $U$ with residue field $\mathbb {F}_{q^{e}}$, then $x$ is contained in $C_n$ for all $n\geq e$. By Lemma 2.9, it follows that there exist an infinite set $S\subset \mathbb {N}$ and sections $\tilde {t}_0,\dots,\tilde {t}_m\in H^{0}(\bar {X},\omega ^{r}_N)$ such that the induced rational map $\tilde {f}\colon \bar {X}\dashrightarrow \mathbb {P}^{m}$ lands in $\mathscr {A}^{*}_{8g,1,l}$ and, moreover, for each $n\in S$, we have an equality of morphisms $\tilde {f}|_{\bar {C}_n}=f_n$.
By shrinking $U$, we therefore obtain a map $\tilde {f}\colon U\rightarrow \mathscr {A}_{8g,1,l}$ and hence an abelian scheme ${B_U\rightarrow U}$ such that $B_U[l]$ is a trivial étale cover of $U$. The maps $f_n\colon \bar {C}_n\rightarrow \mathscr {A}_{8g,1,l}^{*}$ were all constructed such that the induced abelian scheme $B_{C_n}\rightarrow C_n$ is compatible with
On the other hand, if $u$ is a closed point of $U$, then $u$ lies on $C_n$ for all $n\gg 0$. We claim that it follows that $B_U\rightarrow U$ is compatible with $(L\oplus L^{*}(-1))^{4}|_U$. Indeed, it suffices to show that for every closed point $u$ of $U$, $B_u\rightarrow u$ and $(L\oplus L^{*}(-1))^{4}|_u$ are compatible, that is, that the characteristic polynomials of Frobenius match up. Pick $n\in S$ with $C_n$ containing $u$. As the map $\tilde {f}\colon U\rightarrow \mathscr {A}_{8g,1,l}$ extends the map $f_n\colon C_n\rightarrow \mathscr {A}_{8g,1,l}$ by the definition of $S$ in Lemma 2.9, the induced abelian scheme $B_U\rightarrow U$ extends the abelian scheme $B_{C_n}\rightarrow C_n$ constructed above, which is compatible with $(L\oplus L^{*}(-1))^{4}|_{C_n}$ by construction. Therefore $B_u\rightarrow u$ is compatible with $(L\oplus L^{*}(-1))^{4}|_{u}$, as desired.
For each $n\in S$ we have that $\tilde {f}|_{\bar {C}_n}=f_n$. By construction there exists an abelian scheme $A_{C_n}\rightarrow C_n$ of dimension $g$ with
Consider the map of representations induced by the first ${{\mathbb {Z}}}_l$-cohomology of the abelian schemes $B_U\rightarrow U$ and $B_U|_{C_n}\rightarrow C_n$:
Then [Reference KatzKatz01, Lemma 6(b)] implies that for $n\gg 0$, the two representations have the same image (which lands in $\mathrm {GL}_{2g}({{\mathbb {Z}}}_l)^{8}$). By the fundamental work of Tate and Zarhin on Tate's isogeny theorem for abelian varieties over finitely generated fields of positive characteristic [Reference Moret-BaillyMB85, Ch. XII, Théorème 2.5(i), p. 244], it follows that, for all $n\gg 0$, the natural injective map $\text {End}_U(B_U)\hookrightarrow \text {End}_{C_n}({B_U|_{C_n}})$ is an isomorphism when tensored with ${{\mathbb {Z}}}_l$ and hence also when tensored with ${{\mathbb {Q}}}_l$. Therefore, for all $n\gg 0$, the map
is an isomorphism as both sides are finite-dimensional semi-simple ${{\mathbb {Q}}}$-algebras of the same rank.
We know that $\text {End}_{C_n}(B_{U}|_{C_n})$ has a non-trivial idempotent $e_{C_n}$ that projects onto a copy of $A_{C_n}$. After replacing $e_{C_n}$ by a high integer multiple, we may lift $e_{C_n}$ to $e_U\in \text {End}_U(B_U)$. Set the image of $e_U$ to be the abelian scheme $\pi _U\colon A_U\rightarrow U$. Finally, we claim that $A_U$ is compatible with $L$ (equivalently, ${{\mathcal {E}}}$). Indeed, the image $A_U\rightarrow U$ is an abelian scheme of dimension $g$ that extends $A_{C_n}\rightarrow C_n$. On the other hand, in (3.6) the two images in $\mathrm {GL}_{16g}(\mathbb {Z}_l)$ are the same (as we have assumed $n\gg 0$) and hence have corresponding decompositions in irreducible $\mathbb {Q}_l$ representations.
Step 3: the proof in the general case via reduction to Step 2. There exists a projective divisorial compactification $\bar {X}$ of $X$. (This means that $\bar {X}$ is normal and the boundary is an effective Cartier divisor.) By Kedlaya's semi-stable reduction theorem (see [Reference KedlayaKed22, Theorem 7.6] for a meta-reference), there is a generically étale alteration $\varphi \colon X'\rightarrow X$ together with a simple normal crossings compactification $\overline {X'}$ such that the overconvergent pullback ${{\mathcal {E}}}'$ extends to a logarithmic $F$-isocrystal with nilpotent residues. After replacing $X'$ with a further finite étale cover, we may guarantee that the residual representation of $L'$ is trivial.
We have proven the theorem for ${{\mathcal {E}}}'$ on $X'$: there exist an open subset $W'\subset X'$ and an abelian scheme $A_{W'}\rightarrow W'$ of relative dimension $g$ with $\mathbb {D}(A_{W'}[p^{\infty }])\cong {{\mathcal {E}}}'|_{W'}$. After shrinking $W'$ and $W$, we may assume that $\varphi |_{W'}\colon W'\rightarrow W$ is finite étale, of degree $d$.
Set $B_W:=\mathfrak {Res}^{W'}_{W}(A_{W'})$ to be the Weil restriction of scalars. This is an abelian scheme over $W$ of dimension $dg$. We claim that $B_W$ is compatible with $L^{d}$. One way to see this is as follows. Consider the short exact sequence of abelian sheaves in the étale topology:
As $W'\rightarrow W$ is finite étale, Weil restriction is exact on the level of abelian étale sheaves. Therefore $\mathfrak {Res}^{W'}_W(A_{W'}[l^{n}])\cong B_W[l^{n}]$. As $A_{W'}[l^{n}]$ is a finite étale group over $W$, one deduces that the representation associated to $B_W$ is isomorphic to
However, $L'$, as a representation, is the restriction of $L$ along the inclusion $\pi _1(W')\hookrightarrow \pi _1(W)$. Then the desired compatibility follows from the following fact: if $H\subset G$ is the inclusion of a subgroup of finite index $d$, and if $V$ is a finite-dimensional representation of $G$, then
Recall that we wrote an isotypic decomposition:
where each $L_i$ is irreducible on $X$ (and hence on $W$ by [Reference KedlayaKed18, Lemma 1.1.2]). Let $E_i\subset \overline {\mathbb {Q}}_l$ denote the field generated by the traces of Frobenius on $L_i$ as $x$ ranges through the closed points of $W$. We claim that we may find a smooth curve $C\subset W$ with the following properties:
(1) each $L_i|_C$ is irreducible;
(2) the field generated by Frobenius traces of $L_i|_C$ is $E_i\subset \overline {\mathbb {Q}}_l$;
(3) each $L_i|_{C}$ has infinite monodromy around $\infty$; and
(4) the induced monodromy representations coming from $B_W\rightarrow W$ and $B_W|_C\rightarrow C$
have the same image.
We have a projective normal compactification $\bar {X}$ of $X$, which is smooth away from a closed subset of codimension at least $2$. Let $F=\bar {X}\backslash X$ and let $F'\subset F$ be the singular locus of $\bar {X}$. For each $L_i$, there is an irreducible component $F_j$ of $F$ that witnesses the fact that $L_i$ has infinite monodromy at $\infty$: having infinite monodromy at $\infty$ means that a certain inertia group has infinite image in the representation.
Pick a closed point $y_j\in F_j\backslash (F_j\cap F')$ for each $j$. Then, by using [Reference DrinfeldDri12, C.2], we may construct an infinite set of curves $(C_n)_{n\in {{\mathbb {N}}}}$ where each $C_n\subset W$ is a smooth, geometrically connected curve that contains all closed points of $W$ whose residue fields are contained in $\mathbb {F}_{q^{n!}}$ and that pass through the $y_j$ transversally (i.e., with a tangent direction that is not contained in $F_j$). (We remark that this is a consequence of Poonen's Bertini theorem [Reference PoonenPoo04, Theorem 1.3].)
Each $L_i|_{C_n}$ has infinite monodromy around $\infty$. By [Reference KatzKatz01, Lemma 6(b)], it follows that for all $n\gg 0$, $C_n$ satisfies (4). For $n\gg 0$, [Reference KatzKatz01, Lemma 6(b)] and [Reference DeligneDel12] guarantee that setting $C:=C'_n$ satisfies the above four conditions.
Again, by using Drinfeld's Theorem 2.1, Remark 2.8, and (3.1) as in Step 2, there exists an abelian scheme $A_{C}\rightarrow C$ that is compatible with $L|_{C}$. On the one hand, using the Tate isogeny theorem [Reference Moret-BaillyMB85, Ch. XII, Théorème 2.5], it follows that $A^{d}_C$ is isogenous to $B_W|_C$. On the other hand, another application the Tate isogeny theorem together with property (4) of $C$ implies that the natural map
is an isomorphism after tensoring with ${{\mathbb {Q}}}$. As $B_W|_C$ is isogenous to $A_C^{d}$, it follows that $\text {End}_{C}(B_W|_C)\otimes {{\mathbb {Q}}}$ has an element $e_{C}$ projecting onto a factor of $A_C$. After replacing $e_C$ with a high integer multiple, we may lift to $e_W\in \text {End}_W(B_W)$. Set the image of $e_W$ to be the abelian scheme $A_W\rightarrow W$; this is compatible with $L|_W$, as desired.
Proof of Corollary 1.3 Suppose there exists $\pi _U\colon A_U\rightarrow U$ such that $R^{1}(\pi _U)_*\overline {\mathbb {Q}}_l$ has $L_1$ as a summand. By the assumption that $X$ is smooth and geometrically connected, it is irreducible; hence $U\subset X$ is dense. A theorem of Zarhin implies that $R^{1}(\pi _U)_*\mathbb {Q}_l$ is semi-simple [Reference Moret-BaillyMB85, Chapitre XII, Theorem 2.5, pp. 244–245]. The field generated by the characteristic polynomials of $R^{1}(\pi _U)_*\mathbb {Q}_l$ is clearly ${{\mathbb {Q}}}$; indeed, this follows Weil's theorem that the characteristic polynomial of Frobenius acting on the Tate module of an abelian variety over a finite field has coefficients in $\mathbb {Z}$ [Reference WeilWei48, IX,X].
We claim that $\mathbb {D}(A_U[p^{\infty }])\otimes \mathbb {Q}_p$ is a semi-simple object of $\textbf {F-Isoc}^{{\dagger} }({U})$. This is essentially contained in [Reference PálPál15, Remark 4.11], but some comments are in order.
While the statement of [Reference PálPál15, Remark 4.11] assumes that $U$ is a smooth curve, this assumption is unnecessary. Indeed, the only point where this assumption is used is in the citation of [Reference Kato and TrihanKT03, 4.3–4.8], to argue that the associated $F$-isocrystal is overconvergent. However, [Reference ÉtesseÉte02, Théorème 7] essentially states and proves exactly this: if $S/k$ is a smooth separated scheme over a field $k$ of characteristic $p$ and $A\rightarrow S$ is an abelian scheme, then $R^{1}f_{\text {rig}}(\mathcal {O}_{X/K})$ is an overconvergent $F$-isocrystal on $S$. When $k$ is perfect, this $F$-isocrystal is isomorphic to $R^{1}f_{\text {crys}}(\mathcal {O}_{X/W})\otimes \mathbb {Q}$ because $A\rightarrow S$ is smooth and proper (see, for example, [Reference BerthelotBer97, Proposition 1.9]). On the other hand, $R^{1}f_{\text {crys}}(\mathcal {O}_{X/W})\cong \mathbb {D}(A[p^{\infty }])$. In particular, to obtain the semi-simplicity, one simply combines Corollary 4.9 and Proposition 3.5 of [Reference PálPál15] with the fact that $\mathbb {D}(A_U[p^{\infty }])\in \textbf {F-Isoc}^{{\dagger} }({U})$, exactly as explained in [Reference PálPál15, Remark 4.11].
As $\mathbb {D}(A_U[p^{\infty }])\otimes \mathbb {Q}_p$ is isomorphic to the rational crystalline cohomology of $A_U\rightarrow U$, it follows from [Reference Katz and MessingKM74] that $\mathbb {D}(A_U[p^{\infty }])\otimes \mathbb {Q}_p$ and $R^{1}(\pi _U)_*\mathbb {Q}_l$ are companions. It follows from Lemma 2.5 that all crystalline companions of $L_1|_U$ exist and, moreover, are summands of $\mathbb {D}(A_U[p^{\infty }])\otimes \overline {\mathbb {Q}}_p$. Then, by [Reference KedlayaKed18, Corollary 3.3.3], all crystalline companions to $L_1$ exist.
Conversely, suppose all crystalline companions $({{\mathcal {E}}}_i)^{b}_{i=1}$ to $L_1$ exist. We first of all claim that each ${{\mathcal {E}}}_i$ has infinite monodromy at $\infty$. Indeed, suppose for contradiction that there existed an alteration $f\colon X'\rightarrow X$ and a compactification $\overline {X'}$ such that $f^{*}{{\mathcal {E}}}_i$ extends to an object ${{\mathcal {F}}}'$ of $\textbf {F-Isoc}^{{\dagger} }({\overline {X'}})_{\overline {\mathbb {Q}}_p}$. Then $f^{*}L_1$ would also extend to $\overline {X'}$ by [Reference KedlayaKed18, Corollary 3.3.3], contradicting the assumption that $L_1$ had infinite monodromy at $\infty$. Moreover, each ${{\mathcal {E}}}_i$ is irreducible by [Reference KedlayaKed18, Lemma 3.3.1]. Similarly, tensorial operations respect the companion relation, hence $\det ({{\mathcal {E}}}_i)\cong \overline {\mathbb {Q}}_p(-1)$. There exists a $p$-adic local field $K$ with each ${{\mathcal {E}}}_i$ an object of $\textbf {F-Isoc}^{{\dagger} }({X})_{K}$. Set ${{\mathcal {E}}}:=\bigoplus _{i=1}^{b} {{\mathcal {E}}}_i$, considered as an object of $\textbf {F-Isoc}^{{\dagger} }({X})$ (by restricting scalars from $K$ to $\mathbb {Q}_p$, so the rank of ${{\mathcal {E}}}$ is $2b[K:{{\mathbb {Q}}}]$). Note that ${{\mathcal {E}}}$, being the sum of irreducible objects, is semi-simple. Then ${{\mathcal {E}}}$ satisfies the hypotheses of Theorem 1.2, and $L_1$ is a companion of a summand of ${{\mathcal {E}}}$. It follows that there is an open set $U\subset X$ together with an abelian scheme $\pi _U\colon A_U\rightarrow U$ such that ${{\mathcal {E}}}\cong \mathbb {D}(A_U[p^{\infty })\otimes \mathbb {Q}_p$. Again using Zarhin's semi-simplicity, $L_1|_U$ is a summand of $R^{1}(\pi _U)_*\overline {\mathbb {Q}}_l$, as desired.
Proof of Corollary 1.4 Under the assumption on $E_1$, all $p$-adic companions to ${{\mathcal {E}}}_1$ exist by [Reference Krishnamoorthy and PálKP21, Corollary 4.16]. (This result is straightforward; they are all Galois twists of each other.) Fix $\sigma \colon \overline {\mathbb {Q}}_p \rightarrow \overline {\mathbb {Q}}_l$. Then the $\sigma$-companion to ${{\mathcal {E}}}_1$ exists by [Reference Abe and EsnaultAE19, Theorem 4.2] or [Reference KedlayaKed18, Corollary 3.5.3]. Apply Corollary 1.3.
Appendix A. Logarithmic $F$-crystals
We first recall the notion of a logarithmic $F$-crystal/isocrystal. While this notion is due to Kato [Reference KatoKato89, § 6], our treatment is copied from recent work of Kedlaya.
Definition A.1 A smooth pair over a perfect field $k$ is a pair $(Y,Z)$ where $Y/k$ is a smooth variety and $Z\subset Y$ is a strict normal crossings divisor.
Definition A.2 Let $(Y,Z)$ be a smooth pair over a perfect field $k$ of characteristic $p>0$. A smooth chart for $(Y,Z)$ is a sequence of elements $\bar {t}_1,\dots,\bar {t}_n$ of elements of ${{\mathcal {O}}}_Y(Y)$ such that
• the induced map $\bar {f}\colon Y\rightarrow \mathbb {A}^{n}$ is étale, and
• there exists an $m\in [1,n]$ such that the zero-loci of $\overline {t_i}$, for $i=1,\dots, m$, are exactly the irreducible components of $Z$.
Smooth charts exist Zariski locally on smooth pairs (in characteristic $p$) by [Reference KedlayaKed05, Theorem 2]. Let $(Y,Z)$ be a smooth pair over a perfect field $k$ of characteristic $p>0$. Let $\bar {t}_1,\dots,\bar {t}_n$ be a smooth chart of $(Y,Z)$. Let $P_0$ be the formal scheme given by the formal completion of $W(k)[t_1,\dots,t_n]$ along $(p)$. By topological invariance of the étale site, there exist a unique smooth formal scheme $P$ and an étale morphism $f\colon P\rightarrow P_0$ lifting $\bar {f}$. We call the pair $(P,t_1,\dots,t_n)$ the lifted smooth chart of $(Y,Z)$ associated to the original chart.
Let $\sigma _0\colon P_0\rightarrow P_0$ be the Frobenius lift with $\sigma ^{*}(t_i)=t_i^{p}$ for $i\in [1,\dots,n]$. Then there exists an associated Frobenius lift $\sigma \colon P\rightarrow P$.
Definition A.3 Let $(Y,Z)$ be a smooth pair over a perfect field $k$ and let $\bar {t}_1,\dots,\bar {t}_n$ be a smooth chart of $(Y,Z)$. Keep notation as above. A logarithmic crystal with nilpotent residues on $(Y,Z)$ is a pair $(M,\nabla )$ where:
• $M$ is a $p$-torsion free coherent module over $P$; and
• $\nabla$ is an integrable, topologically quasi-nilpotent connection on $M$ (with respect to $W(k)$) with logarithmic poles and nilpotent residues along the zero-loci of $f^{*}(t_i)$ for $i\in 1,\dots,m$.
A logarithmic $F$-crystal with nilpotent residues is a triple $(M,\nabla,F)$ where $(M,\nabla )$ is a logarithmic crystal with nilpotent residues and $F$ is an injective, horizontal morphism
of coherent $P$-modules. A logarithmic Dieudonné crystal with nilpotent residues is a quadruple $(M,\nabla,F,V)$ where $(M,\nabla,F)$ is a logarithmic $F$-crystal in finite, locally free modules with nilpotent residues and $V$ is an injective, horizontal map
such that $FV=VF=p$.
Remark A.4 In the definition of a logarithmic $F$-crystal with nilpotent residues, we do not demand that $M$ is locally free. However, in our definition of a logarithmic Dieudonné crystal, we do demand that the underlying logarithmic crystal is locally free.
This definition extends to general smooth pairs by Zariski gluing; every smooth pair admits a finite open covering on which the restriction admits a smooth chart. We often drop the connection $\nabla$ from the notation and write a logarithmic $F$-crystal as $(M,F)$.
There is a natural category of logarithmic crystals with nilpotent residues on $(Y,Z)$ (where morphisms are $P$-linear and horizontal), and the category of logarithmic isocrystals with nilpotent residues is defined to be the induced isogeny category. One similarly defines the category of logarithmic $F$-isocrystals with nilpotent residues.
Remark A.5 Part of the definition of a logarithmic $F$-crystal $(M,\nabla,F)$ in Definition A.3 explicitly assumes that the residues of the underlying crystal $(M,\nabla )$ were nilpotent. This assumption is indeed superfluous; we now explain why.
First of all, the associated logarithmic isocrystal $(M,\nabla )\otimes {{\mathbb {Q}}}$ to $(M,\nabla,F)$ is a convergent logarithmic isocrystal: indeed, a logarithmic isocrystal is convergent if and only if it is infinitely Frobenius divisible; see [Reference OgusOgu95, Remark 16], the argument of which is just a logarithmic variant of [Reference OgusOgu84, 2.18]. (See [Reference BerthelotBer96, § 2.4] or [Reference Esnault and ShihoES18, Remark 2.4] for several other perspectives in the non-logarithmic setting.) Then it is a general fact that a convergent logarithmic $F$-isocrystal has nilpotent residues; see, for example, [Reference KedlayaKed22, Definition 7.2].
Remark A.6 Let $(Y,Z)$ be a smooth pair over $k$ and let $U=Y\backslash Z$. We denote by $\underline {Y}$ the (fine, saturated) logarithmic scheme given by $(Y,\alpha \colon {{\mathcal {O}}}_U^{*}\hookrightarrow {{\mathcal {O}}}_Y)$. Then our definition of a logarithmic crystal is compatible with the definition of Kato (see [Reference KatoKato89, Theorem 6.2]), our definition of a logarithmic $F$-crystal in finite, locally free modules is compatible with the definition of Kato and Trihan (see [Reference Kato and TrihanKT03, 4.1]) and our definition of a logarithmic $F$-isocrystal is compatible with the definition given by Shiho (see [Reference ShihoShi00, Definition 4.1.3]).
The mathematical content of the following lemma is essentially [Reference KatzKatz79, Theorem 2.6.1] (and relatedly [Reference CrewCre87, Lemma 2.5.1]); we have simply rewritten Katz's argument in the logarithmic setting. The key is that Katz's slope bounds holding on the open subset where the logarithmic structure is trivial guarantees that they hold everywhere. We use Kato's definition of logarithmic $F$-crystals only for convenience to discuss global objects; all of the computations use the local definitions given above.
Lemma A.7 Let $(Y,Z)$ be a smooth pair over a perfect field $k$ of positive characteristic and let $U:=Y\backslash Z$. Let ${{\mathcal {E}}}$ be a logarithmic $F$-isocrystal on $(Y,Z)$.
(1) Suppose the Newton slopes of ${{\mathcal {E}}}_U$ are all non-negative. Then there exist an open subset $W\subset Y$, whose complementary codimension is at least $2$, and a logarithmic $F$-crystal in finite, locally free modules $(M'',F)$ on the smooth pair $(W,W\cap Z)$ such that ${(M'',F)\otimes {{\mathbb {Q}}}\cong {{\mathcal {E}}}_W}$.
(2) Suppose the Newton slopes of ${{\mathcal {E}}}_U$ are in the interval $[0,1]$. Then there exist an open subset $W\subset Y$, whose complementary codimension is at least $2$, and a logarithmic Dieudonné crystal in finite, locally free modules $(M'',F,V)$ on the smooth pair $(W,W\cap Z)$ such that $(M'',F)\otimes {{\mathbb {Q}}}\cong {{\mathcal {E}}}_W$.
Proof. By the definition of a logarithmic $F$-isocrystal, there exist a logarithmic crystal in coherent (not necessarily locally free!) modules $M$ and a map $F\colon \textit {Frob}_{\underline Y}^{*} M\rightarrow M\otimes {{\mathbb {Q}}}$ that is isomorphic to ${{\mathcal {E}}}$ when thought of as a logarithmic $F$-isocrystal. Here, $\textit {Frob}_{\underline Y}$ refers to the absolute Frobenius (on the fine and saturated (f.s.) log scheme $\underline {Y}$ induced from the smooth pair $(Y,Z)$) and the $*$ refers to pullback on the logarithmic crystalline topos. This is compatible with our above definitions.
As $M$ is a logarithmic crystal in coherent modules, there exists a non-negative integer $\nu$ so that
We have assumed that the Newton slopes of ${{\mathcal {E}}}$ are all non-negative. Slope bounds of Katz (see the proof on [Reference KatzKatz79, pp. 151–152]) imply then that there exists a non-negative $\nu$ such that, for all $n\geq 0$,
We explicate this in local coordinates. Take an affine open neighborhood $T\subset Y$ such that $(T,T\cap Z)$ has a smooth chart $(\bar {t}_1,\dots,\bar {t}_n)$. Let $(P,t_1,\dots,t_n)$ be the associated lifted smooth chart; note that $P=\text {Spf}(A)$ where $A$ is a noetherian $W(k)$ algebra equipped with the $p$-adic topology. Then the logarithmic crystal yields a finitely generated $A$ module $M_A$ and the Frobenius structure induces a continuous, $A$-linear homomorphism $F\colon \sigma ^{*}M_A\rightarrow p^{-\mu }M_A$.
As $U\cap T\subset T$ is open dense, it follows from (A.1) that
By varying $T$, one deduces that $F^{n}\colon (\textit {Frob}^{n}_{\underline Y})^{*}M\rightarrow p^{-\nu }M$ for our fixed $\nu$ as above and for all $n\geq 0$.
Consider the module
As $A$ is noetherian, $M_A'$ is finitely generated, being a submodule of a finitely generated module. Moreover, $M_A'$ is stable under $F$. Finally, $M_A'$ is the finite sum of (logarithmic) horizontal submodules. Therefore the pair $(M_A',F)$ is in fact a logarithmic $F$-crystal in coherent modules. We have an isomorphism $(M_A',F)\otimes {{\mathbb {Q}}}\cong {{\mathcal {E}}}_T$ in the category of logarithmic $F$-isocrystals with nilpotent residues on $(T,Z\cap T)$.
Now set $M_A'':=(M_A')^{**}$. This is a coherent reflexive sheaf on the ring $A$, and hence is locally free away on an open set of $\operatorname {Spec}(A)$ whose complement has codimension at least 3 [Sta20, 0AY6]. $M_A''$ is manifestly stable under the connection and $F$. In particular, we can find an open subset $T''\subset T$ with complementary codimension at least $2$ such that the logarithmic $F$-crystal $(M_A'',F)_{T''}$ is a crystal in finite, locally free modules.
After initially choosing a pair $(M,F\colon \textit {Frob}_{\underline {Y}}^{*}M\rightarrow p^{-\mu }M)$ representing ${{\mathcal {E}}}$, the constructions we have made are canonical. Therefore, ranging over $T$, we may glue the $(M'',F)_{T''}$; that is, there is an open subset $W\subset T$ with complementary codimension at least $2$ and a logarithmic $F$-crystal $(M'',F)_W$ in finite, locally free modules on the smooth pair $(W,Z\cap W)$ that is a lattice inside of ${{\mathcal {E}}}_W$.
We now indicate how to complete the result if the Newton polygons on $U$ are in the interval $[0,1]$. Let $(M,F)$ be a logarithmic $F$-crystal in finite, locally free modules on a smooth pair $(Y,Z)$ over a perfect field $k$ and suppose the Newton slopes on $U$ are no greater than 1. Set $V:=F^{-1}\circ p$. Then $V$ does not necessarily stabilize $M$; however, the pair $(M,V)_U$ is a logarithmic $\sigma ^{-1}$-$F$-isocrystal in the language of [Reference KatzKatz79]. (Fortunately, Katz's entire paper is written in the context of $\sigma ^{a}$-$F$-crystals for any $a\neq 0$, not just the positive $a$. In particular, all of Katz's results also hold for $\sigma ^{-1}$-$F$-crystals. Katz does not deal with logarithmic crystals, but we only use the slope bounds on the open set $U$.) By the coherence argument as above, we may find $\eta$ such that
on all of $Y$. Again, using Katz's slope bounds on $U$ (which hold equally well for $\sigma ^{-1}$-$F$-crystals) and the same coherence argument, one shows that after possibly increasing $\eta$, we in fact have
for all $n\geq 0$. Now run exactly the above argument with $V$ instead of $F$: then
will be coherent, horizontal, and stabilized by $V$. Recall that $FV=VF=p$; therefore, $M'$ is also stabilized by $F$! Then $M'':=(M')^{**}$ is a reflexive logarithmic crystal on $(Y,Z)$ that is stabilized by both $F$ and $V$. Exactly as above, there exists an open subset $W\subset Y$ of complementary codimension at least $2$ such that $(M'',F,V)_W$ is a logarithmic Dieudonné crystal in finite, locally free modules, as desired.
Remark A.8 Let $(Y,Z)$ be a smooth pair over $k$ and let $(M,F,V)$ be a logarithmic Dieudonné crystal (in finite, locally free modules) on $(Y,Z)$. We construct a natural line bundle $\omega$, which we call the Hodge line bundle, attached to $(M,F,V)$.
Evaluating $M$ on the trivial thickening of $(Y,Z)$, we obtain a vector bundle $M_{(Y,Z)}$ on $Y$ together with an integrable connection with logarithmic poles on $Z$ and a horizontal map:
The kernel is a vector bundle on $Y$. Set $\omega :=\det (\text {ker}(F_{(Y,Z)}))$. We call $\omega$ the Hodge line bundle associated to $(M,F)$.
As a reference for this remark: in the case when $Z$ is empty, one finds this construction in [Reference de JongdJ98, 2.5.2 and 2.5.5]. In the setting of logarithmic Dieudonné crystals, Kato and Trihan construct the dual object: $Lie(M,F,V)$ (see [Reference Kato and TrihanKT03, 5.1] and especially [Reference Kato and TrihanKT03, Lemma 5.3]. Note that this lemma holds in our situation: our hypothesis that $(Y,Z)$ is a smooth pair over a perfect field $k$ implies that the conditions of 5.1 of [Reference Kato and TrihanKT03, p. 563] hold: étale locally, there is a $p$-basis of $Y$ such that each (regular) component of $Z$ is cut out by some member of the $p$-basis.
Remark A.9 Let $Y/k$ be a smooth scheme over a perfect field $k$. Let $A_Y\rightarrow Y$ be an abelian scheme. Then there is an associated Dieudonné crystal $(M,F,V)=\mathbb {D}(A_Y[p^{\infty }])$ on $Y$ [Reference Berthelot, Breen and MessingBBM82]. The Hodge bundle of $(M,F)$ is isomorphic to the Hodge line bundle of the abelian scheme $A_Y\rightarrow Y$ by [Reference Berthelot, Breen and MessingBBM82, 3.3.5 and 4.3.10].
Finally, we have the following key Proposition A.11, which furnishes several compatibilities that we need for our main argument. The proof of the proposition largely amounts to collating well-known results in the theory of $F$-(iso)crystals. We first require the following setup.
Setup A.10 Let $C/k$ be a smooth, proper, geometrically irreducible curve over a perfect field $k$ of characteristic $p>0$, let $U\subset C$ be an open dense subset, and let $Z\subset C$ be the reduced complement. Let $A_U\rightarrow U$ be an abelian scheme with semi-stable reduction along $Z$. Call the Néron model $A_C\rightarrow C$. Then there is an attached logarithmic Dieudonné crystal on $(C,Z)$, which we call $\mathbb{D}^{\log}(A_C)$ [Reference Kato and TrihanKT03, 4.4–4.8]. (Kato and Trihan construct a covariant Dieudonné functor. We assume ours is contravariant, which may be accomplished by taking a dual as in [Reference Kato and TrihanKT03, 4.1].)
Proposition A.11 In the context of Setup A.10, the following assertions hold.
(1) The (non-logarithmic) Dieudonné crystal $\mathbb{D}^{\log}(A_C)|_U$ is isomorphic to the crystalline Dieudonné module of the $p$-divisible group $A_U[p^{\infty }]$
(2) Let $A^{o}_C\rightarrow C$ be the semi-abelian scheme associated to $A_C\rightarrow C$, obtained by removing the non-identity components of the fibers over $Z$.The Hodge line bundle of $A^{o}_C\rightarrow C$, is isomorphic to the Hodge line bundle of the logarithmic Dieudonné crystal $\mathbb{D}^{\log}(A_C)$ described in Remark A.8.
(3) The logarithmic Dieudonné crystal $\mathbb{D}^{\log}(A_C)$ is the unique logarithmic Dieudonné crystal (with nilpotent residues) on $(C,Z)$ that extends $\mathbb {D}(A_U[p^{\infty }])$.
Proof. We prove each point in turn. Point (1) follows by the construction of the logarithmic Dieudonné module: see the description of gluing as in [Reference Kato and TrihanKT03, Lemma 4.4.1].
Point (2) is given in [Reference Kato and TrihanKT03, Example 5.4(b)], with the caveat that they work with the covariant Dieudonné functor and $\text {Lie}(A_C\rightarrow C)$.
We now prove point (3). First of all, note that we only need to check that there is at most one extension as a logarithmic $F$-crystal in finite, locally free modules. In our setting, $V$ is determined by $F$ under the relation $FV=VF=p$. By [Reference ÉtesseÉte02, Théorème 7], it follows that $\mathbb {D}(A_U[p^{\infty }])\otimes \mathbb {Q}_p$ is overconvergent. Forgetting the $V$-structure, we are left with a logarithmic $F$-crystal $(M,F)$ on $(C,Z)$. (By Remark A.5, the residues of $(M,F)$ are automatically nilpotent.) Note that $(M,F)|_U$ is an overconvergent $F$-crystal by [Reference KedlayaKed04].
We are now able to prove the desired uniqueness. Let $(N,F)$ be a logarithmic $F$-crystal on $(C,Z)$ such that $(M,F)|_U\cong (N,F)|_U$. (By the above, $(N,F)$ automatically has nilpotent residues along $Z$.) We introduce the following notation.
• $\textbf {FC}({C,Z})$ is the category of logarithmic $F$-crystals in finite, locally free modules (with nilpotent residues) on $(C,Z)$.
• $\textbf {FC}({U})$ is the category of $F$-crystals in finite, locally free modules on $U$.
• $\textbf {F-Isoc}({C,Z})$ is the category of logarithmic $F$-isocrystals (with nilpotent residues) on $(C,Z)$.
• $\textbf {F-Isoc}({U})$ is the category of (convergent) $F$-isocrystals (with nilpotent residues) on $U$.
Consider the following diagram:
To prove that $(M,F)\cong (N,F)$ in the category $\textbf {FC}({C,Z})$, it suffices to show that the top horizontal arrow is an isomorphism. We first prove that this arrow is injective with torsion cokernel; then we will show that the image is $p$-saturated.
The natural map
is an isomorphism by a full-faithfulness result of Kedlaya [Reference KedlayaKed07, Theorem 6.4.5]. It follows immediately that the bottom horizontal arrow of (A.2) is an isomorphism. (See also [Reference KedlayaKed22, Theorem 7.3] for exactly this statement.)
The group $\textrm {Hom}_{\textbf {FC}({C,Z})}((M,F),(N,F))$ is a finite free $\mathbb {Z}_p$-module because $(C,Z)/k$ is log smooth. The left vertical arrow of (A.2) is injective because it is simply the map $\otimes {{\mathbb {Q}}}$ on a finite free $\mathbb {Z}_p$-module.
The group $\textrm {Hom}_{\textbf {FC}({U})}((M,F)|_U,(N,F)|_U)$ is a priori only a torsion-free $\mathbb {Z}_p$-module. (In particular, it could have infinite rank.) However, the right vertical arrow fits into the following diagram:
where the vertical arrow is an isomorphism by [Reference KedlayaKed04]. As
is a finite-dimensional $\mathbb {Q}_p$-vector space, it follows that $\textrm {Hom}_{\textbf {FC}({U})}((M,F)|_U,(N,F)|_U)$ is a finite free $\mathbb {Z}_p$-module. As the diagonal arrow is injective (it is the map $\otimes {{\mathbb {Q}}}$), we deduce that
is also injective. Then the top arrow, $\text {res}$, in diagram (A.2) must be injective with torsion cokernel by consideration of the ranks.
Finally, we prove that $\text {res}$ is a saturated map of finite free $\mathbb {Z}_p$ modules. Equivalently, we prove that if $\varphi \in \textrm {Hom}_{\textbf {FC}({C,Z})}((M,F),(N,F))$ is such that $\text {res}(\varphi )$ is divisible by $p$ in $\textrm {Hom}_{\textbf {FC}({U})}((M,F)|_U,(N,F)|_U)$, then $\varphi$ is divisible by $p$. This will use an explicit local calculation with Definition A.3.
Pick smooth charts for $(C,Z)$. More precisely, $C$ may be covered by open subsets $Y_i$ such that there exist étale maps $\bar {f}_i\colon Y_i\rightarrow \mathbb {A}^{1}=\operatorname {Spec}(k[x])$ with the following property: if $Y_i\cap Z\neq \emptyset$, then $Y_i\cap Z=\bar {f}_i^{*}(V(x))$. As both the categories of logarithmic $F$-crystals and usual $F$-crystals are stacks in the Zariski topology, it suffices to prove the desired saturatedness for a single $(Y_i,Y_i\cap Z)$, which we relabel $(Y,Y\cap Z)$. If $Y\cap Z=\emptyset$, there is nothing to prove, so we may assume that $Y\cap Z\neq \emptyset$.
Let $\bar {f}\colon Y\rightarrow \mathbb {A}^{1}$ be an étale map with $\bar {f}^{*}(V(x))=Y\cap Z$, which exists by the definition of $Y$. Let $A_0:=W(k)[x]^{\wedge }$ be the $p$-adic completion of $W(k)[x]$. By topological invariance of the étale site, the map $k[x]\rightarrow \mathcal {O}_Y(Y)$ (with $x\mapsto \bar f$) deforms to an étale map $A_0\rightarrow A$; set $f$ to be the image of $x$ in $A$. Similarly, let $B_0=W(k)[x,x^{-1}]^{\wedge }$ be the $p$-adic completion of $W(k)[x,x^{-1}]$. Again using topological invariance of the étale site, the map $k[x,x^{-1}]\rightarrow \mathcal {O}_Y(Y{\setminus} (Y\cap Z))$ induced from $\bar f$ deforms to an étale map $B_0\rightarrow B$. As $Y\cap Z=\bar {f}^{*}(V(x))$, we have that $B\cong A\hat {\otimes }_{A_0} B_0$. In particular, there is the following diagram of $p$-adic rings:
As in Definition A.3, equip $A_0$ and $B_0$ with the Frobenius lift $\sigma _0$ sending $t\mapsto t^{p}$. Set $\sigma$ to be the induced Frobenius lift on $A$ and $B$.
Let $(M,\nabla,F)$ and $(N,\nabla,F)$ be the realizations of $(M,F)$ and $(N,F)$ on $A$ as in Definition A.3. In particular, $M$ and $N$ are finite, locally free $A$ modules. Then the statement we wish to prove is that
is a saturated map of $\mathbb {Z}_p$ modules, that is, if $\varphi \in \textrm {Hom}_A((M,\nabla,F),(N,\nabla,F))$ is a map such that $\varphi _B$ is divisible by $p$ in $\textrm {Hom}_B((M,\nabla,F)_B,(N,\nabla,F)_B)$, then $\varphi$ was divisible by $p$. In particular, we assume that $\varphi (M_B)\subset pN_B$ and wish to prove that $\varphi (M)\subset pN$; indeed, if $\varphi (M)\subset pN$, then $ {\varphi }/{p}$ will automatically commute with $\nabla$ and $F$ and hence would yield an element $ {\varphi }/{p}\in \textrm {Hom}_A((M,\nabla,F),(N,\nabla,F))$. Therefore, it suffices to prove that if $M$ and $N$ are finite, locally free $A$ modules, then the map $\textrm {Hom}_A(M,N)\rightarrow \textrm {Hom}_B(M_B,N_B)$ is $p$-saturated.
We claim that $A\hookrightarrow B$ is a $p$-saturated map of $p$-adic rings. As noted above, $B\cong A\hat {\otimes }_{A_0} B_0$; therefore, to prove that $A\hookrightarrow B$ is a $p$-saturated, it suffices to prove that $A_0\hookrightarrow B_0$ is $p$-saturated. This map is simply the inclusion $W(k)[x]^{\wedge }\hookrightarrow W(k)[x,x^{-1}]^{\wedge }$, which is clearly $p$-saturated from the explicit description of the elements of the two rings as series.
As $M$ and $N$ are finite locally free $A$-modules, the natural map $\textrm {Hom}_A(M,N)\otimes _A B\rightarrow \textrm {Hom}_B(M_B,N_B)$ is an isomorphism. It follows that the natural map
is $p$-saturated, as desired.
Acknowledgements
This work was born at CIRM (in Luminy) at ‘$p$-adic Analytic Geometry and Differential Equations’; the authors thank the organizers. R.K. warmly thanks Valery Alexeev, Philip Engel, Kiran Kedlaya, Daniel Litt, and especially Johan de Jong, with whom he had stimulating discussions on the topic of this paper. In addition, the authors heartily thank the anonymous referee for a detailed, thorough, and helpful report. R.K. gratefully acknowledges financial support from the NSF under grants no. DMS-1605825 and no. DMS-1344994 (RTG in Algebra, Algebraic Geometry and Number Theory at the University of Georgia).