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The line bundles on the moduli stack of principal bundles on families of curves

Published online by Cambridge University Press:  22 November 2024

Roberto Fringuelli*
Affiliation:
Dipartimento di Matematica, Università di Roma ‘La Sapienza’, Roma, Italy
Filippo Viviani
Affiliation:
Dipartimento di Matematica, Università di Roma ‘Tor Vergata’, Roma, Italy
*
Corresponding author: Roberto Fringuelli, email: [email protected]
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Abstract

Given a connected reductive algebraic group G over an algebraically closed field, we investigate the Picard group of the moduli stack of principal G-bundles over an arbitrary family of smooth curves.

Type
Research Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press on Behalf of The Edinburgh Mathematical Society.

1. Introduction

The aim of this paper, which is a sequel of the papers [Reference Fringuelli and Viviani21] and [Reference Fringuelli and Viviani22], is to study the Picard group of the moduli stack of (principal) G-bundles $\operatorname{\mathrm{Bun}}_G(C/S)$, which parametrizes G-bundles, where G is a connected and smooth linear algebraic group over a field $k=\overline k$, over an arbitrary family $\pi: C\to S$ of (connected, smooth and projective) k-curves of genus $g=g(C/S)\geq 0$.

The moduli stack $\operatorname{\mathrm{Bun}}_G(C)$ of (principal) G-bundles, where G is a complex reductive group and C is a complex curve, has been deeply studied because of its relation to the Wess–Zumino–Witten (=WZW) model associated to G, which form a special class of rational conformal field theories, see [Reference Beauville3], [Reference Sorger41] and [Reference Beauville4] for nice surveys. In the WZW-model associated to a simply connected group G, the spaces of conformal blocks can be interpreted as spaces of generalized theta functions, that is spaces of global sections of suitable line bundles (e.g. powers of determinant line bundles) on $\operatorname{\mathrm{Bun}}_G(C)$, see [Reference Beauville and Laszlo5, Reference Faltings16, Reference Kumar, Narasimhan and Ramanathan28, Reference Laszlo and Sorger31, Reference Pauly37]. The above application to conformal field theory leads naturally to the study of the Picard group of $\operatorname{\mathrm{Bun}}_G(C)$ (for G reductive over $k=\overline k$), which was computed in increasing degree of generality, thanks to the effort of many mathematicians: the case of $\operatorname{SL}_r$ dates back to pioneering work of Drezet–Narasimhan in the late eighties [Reference Drezet and Narasimhan15]; the case of a simply connected, almost simple G is dealt with in [Reference Boysal and Kumar11, Reference Faltings17, Reference Kumar and Narasimhan.29, Reference Laszlo and Sorger31, Reference Sorger42]; the case of a semisimple almost simple G is dealt with in [Reference Beauville, Laszlo and Sorger6, Reference Laszlo30, Reference Teleman43]; the case of an arbitrary reductive group was finally established by Biswas–Hoffmann [Reference Biswas and Hoffmann7].

Motivated by the long-term project of generalizing the study of the vector bundle of conformal blocks (also known as Verlinde bundle) behind the simply connected case, the authors in [Reference Fringuelli and Viviani21] and [Reference Fringuelli and Viviani22] have computed the Picard group of $\operatorname{\mathrm{Bun}}_G({\mathcal C}_{g,n}/{\mathcal M}_{g,n})$, for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ over the moduli stack of n-pointed curves of genus g, as well as the restriction homomorphism to the Picard group of the fibres of $\operatorname{\mathrm{Bun}}_G({\mathcal C}_{g,n}/{\mathcal M}_{g,n})\to {\mathcal M}_{g,n}$, generalizing the previous works of Melo–Viviani [Reference Melo and Viviani33] for $G=\operatorname{\mathbb{G}}_{m}$ and Fringuelli [Reference Fringuelli18] for $G=\operatorname{GL}_r$.

In this follow-up paper, we study the Picard group of $\operatorname{\mathrm{Bun}}_G(C/S)$ for an arbitrary family $C/S$ of curves over an algebraic stack S (which, for technical reasons, it is often assumed to be an integral and regular quotient stack), in which case very little was known before. A remarkable exception is the work of Faltings [Reference Faltings17], which provides a functorial identification $\operatorname{Pic} \operatorname{\mathrm{Bun}}_G(C/S)\cong {\mathbb Z}$ for a simply connected and almost simple group G and an arbitrary family $C/S$ admitting a section. Our Theorem B can be seen as a generalization of Faltings’ result (see Corollary C and the discussion following it).

We can now explain our main results focusing, in this introduction, on families $C/S$ of positive genus $g(C/S) \gt 0$ and referring to the body of the paper for the slightly different, and easier, case $g(C/S)=0$.

Recall that the stack $\operatorname{\mathrm{Bun}}_{G}(C/S)$ is an algebraic stack, locally of finite type and smooth over S and its relative connected components are in functorial bijection with the fundamental group $\pi_1(G)$ (see Fact 2.6). We will denote the connected components and the restriction of the forgetful morphism by

\begin{align*}\Phi_G^{\delta}: \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\to S \quad \text{for any } \delta\in \pi_1(G). \end{align*}

The pull-back morphism at the level of the Picard groups is injective, so will often focus onto the relative Picard group

\begin{align*} \operatorname{RPic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S):=\frac{\operatorname{Pic}\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)}{(\Phi^{\delta})^*(\operatorname{Pic} S)}. \end{align*}

We proved in [Reference Fringuelli and Viviani21, Thm. A] that if $\operatorname{red}: G\twoheadrightarrow G^{\operatorname{red}}$ is the reductive quotient of G, i.e. the quotient of G by its unipotent radical, then for any $\delta\in \pi_1(G)\xrightarrow[\cong]{\pi_1(\operatorname{red})}\pi_1(G^{\operatorname{red}})$, the pull-back homomorphism

\begin{align*} \operatorname{red}_\#^*:\operatorname{Pic}(\operatorname{\mathrm{Bun}}_{G^{\operatorname{red}}(C/S)}^{\delta})\xrightarrow{\cong} \operatorname{Pic}(\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)) \end{align*}

is an isomorphism. Hence, throughout this paper, we will restrict to the case of a reductive group G.

A first source of line bundles on $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$ comes from the determinant of cohomology $d_{\widehat \pi}(-)$ and the Deligne pairing $\langle -,-\rangle_{\widehat \pi}$ of line bundles on the universal curve $\widehat \pi:C\times_S \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$. To be more precise, any character $\chi\in \Lambda^*(G):=\operatorname{Hom}(G, \operatorname{\mathbb{G}}_{m})$ gives rise to a morphism of S-stacks

\begin{align*} \chi_\#:\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to\operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{\chi(d)}(C/S), \end{align*}

and by pulling back via $\chi_{\#}$ the universal $\operatorname{\mathbb{G}}_{m}$-bundle (i.e. line bundle) on the universal curve $C\times_S \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{\chi(\delta)}(C/S)\to\operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{\chi(\delta)}(C/S)$, we get a line bundle $\mathcal L_{\chi}$ on $C\times_S \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$. Then, using these line bundles $\mathcal L_{\chi}$ and the line bundles $\{p_1^*(M)\::\: M\in \operatorname{Pic}(C)\}$ pull-backed from the family $C/S$, we define the following line bundles, that we call tautological line bundles, on $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$

\begin{equation*} \begin{aligned} &\left\{d_{\widehat \pi}({\mathcal L}_{\chi}(M))\: : \chi\in \Lambda^*(G), M\in \operatorname{Pic}(C)\right\},\\ & \left\{\langle {\mathcal L}_{\chi}(M),{\mathcal L}_{\mu}(N)\rangle_{\widehat \pi}: \chi,\mu\in \Lambda^*(G), M,N\in \operatorname{Pic}(C) \right\},\\ \end{aligned} \end{equation*}

where we set ${\mathcal L}_{\chi}(M):={\mathcal L}_{\chi}(p_1^*(M))$ for simplicity.

Note that since any character of G factors through the abelianization of $\mathrm{ab}:G\to G^{\mathrm{ab}}$ of G, the tautological line bundles lie in the subgroup

\begin{align*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\stackrel{\mathrm{ab}_{\sharp}^*}{\hookrightarrow} \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S), \end{align*}

where $\delta^{\mathrm{ab}}:=\pi_1(\mathrm{ab})(\delta)$.

The next theorem describes, for an arbitrary torus T and an arbitrary $d\in \pi_1(T)$ (which includes the case $T=G^{\mathrm{ab}}$ and $\delta^{\mathrm{ab}}=d$), the structure of the tautological subgroup

\begin{align*}\operatorname{Pic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_{T}^{d}(C/S)\subseteq \operatorname{Pic} \operatorname{\mathrm{Bun}}_{T}^{d}(C/S) \end{align*}

generated by the tautological line bundles (or, in other words, it encodes all the relations among tautological line bundles), and it describes when it coincides with the full Picard group.

Theorem A. (see Theorems 3.8 and 3.9) Let CS be a family of curves of genus g > 0 on a regular and integral quotient stack. Let T be a torus and fix $d\in \Lambda(T)=\pi_1(T)$.

  1. (1) The relative tautological Picard group of $\operatorname{\mathrm{Bun}}_{T}^{d}(C/S)$ sits in the following exact sequence, functorial in S and T:

    \begin{equation*} 0 \to \Lambda^*(T)\otimes \operatorname{RPic}(C/S) \xrightarrow{i_{T}^{d}} \operatorname{RPic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_{T}^{d}(C/S) \xrightarrow{\gamma_{T}^{d}} \operatorname{Bil}^s(\Lambda(T)) \to 0, \end{equation*}

    where $\operatorname{RPic}(C/S)$ is the relative Picard group of $C/S$, and the homomorphisms $i_{T}^{d}$ and $\gamma_{T}^{d}$ are defined by

    \begin{align*}i_{T}^{d}(\chi\otimes M)=\langle {\mathcal L}_{\chi}, M\rangle_{\widehat \pi} \quad \text{and } \quad \gamma_{T}^{d}(d_{\widehat \pi}({\mathcal L}_{\chi}(M))=\chi\otimes \chi.\end{align*}
  2. (2) If $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ for a geometric generic point $\overline \eta\to S$ and the natural map $\operatorname{Pic}(C)\rightarrow \operatorname{Pic}_{C/S}(S)$ is surjective, then

    \begin{align*} \operatorname{Pic}\operatorname{\mathrm{Bun}}_{T}^{d}(C/S)=\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_{T}^{d}(C/S). \end{align*}

Moreover, in Theorem 3.8, we give two alternative presentations of the relative tautological Picard group of $\operatorname{\mathrm{Bun}}_{T}^{d}(C/S)$.

The case of families of genus zero curves is easier, and it is dealt with in Theorem 3.6. In particular, we will show that the Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ is always generated by tautological line bundles if $g(C/S)=0$.

The above Theorem A was known:

The other source of line bundles on $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$, for G non-abelian, is the transgression map introduced in [Reference Fringuelli and Viviani21, Thm. 5.0.1, Rmk. 5.2.2]:

\begin{equation*} \tau_G^{\delta}=\tau^{\delta}_G(C/S):(\operatorname{Sym}^2 \Lambda^*(T_G))^{\mathscr W_G}\rightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S), \end{equation*}

which is the homomorphism, functorial in S and G, uniquely characterized the following commutative diagram:

where $\iota:T_G\hookrightarrow G$ is a fixed maximal torus of G, $d\in \pi_1(T_G)$ is any lift of $\delta\in \pi_1(G)$, $\mathscr W_G:={\mathcal N}(T_G)/T_G$ is the Weyl group of G and $(\operatorname{Sym}^2\Lambda^*(T_G))^{\mathscr W_G}$ is identified with the lattice $\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}$ of $\mathscr W_G$-invariant even symmetric bilinear forms on the lattice $\Lambda(T_G)$ of cocharacters of TG (see Lemma 3.13 for an explicit description).

The next theorem describes when the Picard group of $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$ is generated by the image of the transgression map and the pull-back of the line bundles on $\operatorname{\mathrm{Bun}}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)$.

Theorem B. (see Theorems 3.14 and 3.16) Let CS be a family of curves of genus g > 0 on a regular and integral quotient stack. Let G be a reductive group and denote by $\mathrm{ab}:G\to G^{\mathrm{ab}}$ its abelianization. Fix $\delta\in \pi_1(G)$ and set $\delta^{\mathrm{ab}}:=\pi_1(\mathrm{ab})(\delta)\in \pi_1(G^{\mathrm{ab}})$.

If one of the following two hypothesis is satisfied:

  1. (a) the derived subgroup $\mathscr D(G)$ of G is simply connected;

  2. (b) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ for a geometric generic point $\overline \eta\to S$, the natural map $\operatorname{Pic}(C)\rightarrow \operatorname{Pic}_{C/S}(S)$ is surjective and $\operatorname{RPic}^0(C/S)$ is torsion-free;

then the following diagram, which is functorial in G and S,

is a push-out diagram.

In particular, there exists an exact sequence, functorial in S and G,

\begin{align*} 0 \to \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\xrightarrow{\mathrm{ab}_{\sharp}^*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\rightarrow \operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G}\to 0, \end{align*}

where $\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G}$ is the lattice of $\mathscr W_G$-invariant symmetric even bilinear form on $\Lambda(T_{\mathscr D(G)})$ that are integral on $\Lambda(T_{\mathscr D(G)})\otimes \Lambda(T_{G^{\mathrm{ss}}})$, where $G^{\mathrm{ss}}$ is the semisimplification of G.

For a family of curves $C/S$ of positive genus such that $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$, the map $\operatorname{Pic}(C)\rightarrow \operatorname{Pic}_{C/S}(S)$ is surjective and satisfying one of the two assumptions of Theorem B, we give two alternative presentations of the relative Picard group of $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$ in Theorem 3.18.

The case of families of genus zero curves is easier, and it is treated in detail in Theorem 3.20 and Corollary 3.21. In particular, we will show that Theorem B holds true for families of genus zero curves under the assumption that $\mathscr D(G)$ is simply connected (see Theorem 3.14).

For a semisimple group G, the above theorem gives the following:

Corollary C. Let CS be a family of curves of genus g > 0 on a regular and integral quotient stack. Let G be a semisimple group and fix $\delta\in \pi_1(G)$.

If one of the following two hypothesis is satisfied:

  1. (a) G is simply connected,

  2. (b) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ for a geometric generic point $\overline \eta\to S$, the natural map $\operatorname{Pic}(C)\rightarrow \operatorname{Pic}_{C/S}(S)$ is surjective and $\operatorname{RPic}^0(C/S)$ is torsion-free,

then the transgression map

\begin{equation*} \tau_G^{\delta}=\tau^{\delta}_G(C/S):(\operatorname{Sym}^2 \Lambda^*(T_G))^{\mathscr W_G}\xrightarrow{\cong} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \end{equation*}

is an isomorphism, functorial in S and G.

Note that, for G semisimple, we have that $(\operatorname{Sym}^2 \Lambda^*(T_G))^{\mathscr W_G}\cong {\mathbb Z}^s$, where s is the number of almost simple factors of the universal cover $G^{\mathrm{sc}}$ of G (see Lemma 3.13). In particular, if G is simply connected and almost simple (i.e. s = 1), then the above Corollary recovers (in the case where $C/S$ has a section) the isomorphism $ \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\cong {\mathbb Z}$ established by Faltings [Reference Faltings17].

The above Theorem B (and hence Corollary C) was known:

Note that Theorem B does not (necessarily) hold for a curve C over $k=\overline k$ (which clearly does not satisfies assumption (b)) if the group $\mathscr D(G)$ is not simply connected, as it follows from the work of Biswas–Hoffmann [Reference Biswas and Hoffmann7].

In $\S$ 4 of the paper, we consider the rigidification

\begin{equation*} \nu_G^{\delta}:\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S) \to \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\textit{[\!]} \mathscr Z(G):=\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S) \end{equation*}

of the stack $\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)$ by the centre $\mathscr Z(G)$ of G, which acts functorially on any G-bundle.

The Leray spectral sequence for the cohomology of the group $\operatorname{\mathbb{G}}_{m}$ with respect to the $\mathscr Z(G)$-gerbe $\nu_G^{\delta}$ gives the exact sequence

\begin{equation*} 0\to \operatorname{Pic}(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S))\stackrel{(\nu_G^{\delta})^*}{\rightarrow} \operatorname{Pic}(\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)) \xrightarrow{\operatorname{wt}_G^{\delta}} \Lambda^*(\mathscr Z(G)):=\operatorname{Hom}(\mathscr Z(G),\operatorname{\mathbb{G}}_{m}), \end{equation*}

where the weight homomorphism $\operatorname{wt}_G^{\delta}$ is given by restricting the line bundles on $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$ to the fibres of $\nu_G^{\delta}$, and its cokernel measures the triviality of the $\mathscr Z(G)$-gerbe $\nu_G^{\delta}$ (see $\S$ 4 for more details).

In the next theorem, we describe the Picard group of the rigidification $\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S)$ in terms of the Néron–Severi group $\operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta})$ (see Definition 4.1) and the cokernel of the weight homomorphism $\operatorname{wt}_G^{\delta}$ in terms of the cokernel of the evaluation homomorphism $\operatorname{ev}_{\mathscr D(G)}^{\delta}$ (see Definition 4.1).

Theorem D. (see Theorems 4.2 and 4.3) Let CS be a family of curves of genus g > 0 on a regular and integral quotient stack. Assume that both the following conditions hold:

  1. (i) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ for a geometric generic point $\overline \eta\to S$and the natural map $\operatorname{Pic}(C)\rightarrow \operatorname{Pic}_{C/S}(S)$ is surjective;

  2. (ii) either $\operatorname{RPic}^0(C/S)$ is torsion-free or $\mathscr D(G)$ is simply connected.

  1. (1) We have an exact sequence, functorial in S and G:

    \begin{equation*} 0 \to \Lambda^*(G^{\mathrm{ab}})\otimes \operatorname{RPic}^0(C/S) \xrightarrow{\overline{j_G^{\delta}}} \operatorname{RPic}(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S))\xrightarrow{\overline{\gamma_G^{\delta}}} \operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta}), \end{equation*}

    such that

    \begin{equation*} \text{Im}(\overline{\gamma_G^{\delta}})= \left\{b\in \operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta})\: : \: \begin{aligned} & b(\delta\otimes x)+(g-1)b(x\otimes x) \text{ is a multiple of } \delta(C/S) \\ & \text{for any } x\in \Lambda(T_G) \end{aligned} \right\}. \end{equation*}
  2. (2) We have an exact sequence, functorial in S and G:

    \begin{align*} 0\to \operatorname{coker}(\overline{\gamma_G^{\delta}})&\xrightarrow{\partial_G^{\delta}} \operatorname{Hom}\left(\Lambda(G^{\mathrm{ab}}), \frac{{\mathbb Z}}{\delta(C/S){\mathbb Z}}\right)\xrightarrow{\widetilde{\Lambda_{\mathrm{ab}}^*}} \operatorname{coker}(\operatorname{wt}_G^{\delta})\\ &\xrightarrow{\widetilde{\Lambda_{\mathscr D}^*}}\operatorname{coker}(\operatorname{ev}_{\mathscr D(G)}^{\delta})\to 0, \end{align*}

    where $\delta(C/S)$ is the minimum relative degree of a relative ample line bundle on $C/S$ (and zero if such a line bundle does not exist).

The Néron–Severi group $\operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta})$ and the evaluation homomorphism $\operatorname{ev}_{\mathscr D(G)}^{\delta}$ are defined in Definition 4.1. We make explicit Theorem D(2) in the special cases $\delta(C/S)=1$ or G = T a torus in Corollary 4.4.

The case of families of genus zero curves is easier, and it is treated in Theorem 4.5.

Theorem D(1) was known:

Theorem D(2) was known:

The computation of the cokernel of the weight homomorphism $\operatorname{wt}_G^{\delta}$ (which coincides with the kernel of the obstruction homomorphism, see Equation (4.1)) carried over in Theorem D(2) will be used in our upcoming work [Reference Fringuelli and Viviani23], where we will compute the (cohomological) Brauer groups of $\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)$ and $\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S)$ for certain reductive groups, extending the work of Biswas–Holla [Reference Biswas and Holla9] for a fixed curve and a complex semisimple group, as well as the work of Fringuelli–Pirisi [Reference Fringuelli and Pirisi20] for the universal family ${\mathcal C}_{g,n}/{\mathcal M}_{g,n}$ and $G=\operatorname{GL}_r$.

Notations

1.1.

We denote by $k=\overline k$ an algebraically closed field of arbitrary characteristic $p\geq 0$. An algebraic stack will always be assumed locally of finite type over k and quasi-separated, i.e. with quasi-compact and separated diagonal. In particular, all the schemes and algebraic spaces must be quasi-separated. Furthermore, any algebraic space is generically a scheme (see [44, Proposition 06NH])

2. Preliminaries

In this section, we collect some definitions and preliminaries results that we will need throughout the paper.

2.1. Family of curves

A curve is a connected, smooth and projective scheme of dimension one over an algebraically closed field. The genus of a curve C is $g(C):=\dim H^0(C,\omega_C)$.

A family of curves $\pi: C\to S$ is a proper, flat and representable morphism of algebraic stacks whose geometric fibres are curves. If all the geometric fibres of π have the same genus g, then we say that $\pi:C\to S$ is a family of curves of genus g (or a family of curves with relative genus g) and we set $g(C/S):=g$. Note that any family of curves $\pi:C\to S$ with S connected is a family of genus g curves for some $g\geq 0$. For technical reasons, we will often restrict to families of curves $\pi: C\to S$ over a regular and integral quotient stack S over k.

Given $g,n\geq 0$, we denote by ${\mathcal M}_{g,n}$ the algebraic stack parametrizing families of curves of genus g with n ordered and pairwise disjoint sections and by ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ the universal family of n-marked curves of genus g. We omit the n from the notation when it is zero. Note that ${\mathcal M}_{g,n}$ is a DM (=Deligne–Mumford) stack if and only if $2g-2+n \gt 0$.

A family of curves $\pi: C\to S$ is locally projective if, Zariski-locally on the base, it is a closed subscheme of ${\mathbb P}^n_S$ for some $n\geq 1$. Equivalently, $\pi:C\to S$ is locally projective if there exists a π-relatively ample line bundle on C, or equivalently a line bundle on C having π-relative positive degree. Note that a family of curves $\pi:C\to S$ is locally projective if either $g(C/S)\neq 1$ (because the relative dualizing line bundle ωπ has relative degree $2g(C/S)-2$) or π has a section $\sigma:S\to C$. However, there are examples of families of genus one curves without sections that are not locally projective, e.g. the universal family ${\mathcal C}_{1}\to {\mathcal M}_{1}$ of curves of genus one (see Remark 2.2(2), and also [Reference Raynaud39, XIII, 3.2] and [Reference Zomervrucht46] for other examples).

In the results of this paper, an important role is played by the following invariant of the family $C/S$:

Definition 2.1. For a family of curves $C/S$, we define

\begin{align*} \delta(C/S):=\begin{cases} \min\{\deg_{\pi}(M) \gt 0\: : M\in \operatorname{Pic}(C) \}, &\text{if } \pi \text{is locally projective;} \\\ 0, &\text{otherwise.} \end{cases} \end{align*}

Equivalently, if π is locally projective, then $\delta(C/S)$ is the non-negative generator of the non-zero image of the relative degree map

(2.1)\begin{equation} \begin{aligned} \deg_{\pi}:\operatorname{Pic}(C)& \longrightarrow {\mathbb Z},\\ M & \mapsto \deg_{\pi}(M). \end{aligned} \end{equation}
Remark 2.2.

  1. (1) Since the relative dualizing line bundle ωπ of $\pi:C\to S$ has relative degree equal to $2g(C/S)-2$, it follows that

    \begin{align*} \delta(C/S) \: \text{divides }\: 2g(C/S)-2. \end{align*}
  2. (2) It follows from the weak Franchetta conjecture (see [Reference Arbarello and Cornalba2], [Reference Schröer40], [Reference Fringuelli and Viviani24]) that, for the universal family ${\mathcal C}_{g,n} \to {\mathcal M}_{g,n}$ of n-marked curves of genus g, we have that

    \begin{align*} \delta({\mathcal C}_{g,n}/{\mathcal M}_{g,n})= \begin{cases} |2g-2| & \text{if }n=0,\\ 1 & \text{if } n \gt 0. \end{cases} \end{align*}

    Note that $\delta({\mathcal C}_1/{\mathcal M}_1)=0$, which implies that ${\mathcal C}_1\to {\mathcal M}_1$ is not locally projective.

  3. (3) The invariant $\delta(C/S)$ has been computed for many interesting families of curves:

    • If $C/S$ is the universal family of (smooth) complete intersections curves in ${\mathbb P}^r$ of type $(d_1,\ldots, d_{r-1})$, then $\delta(C/S)=d_1\ldots d_{r-1}$ (see [Reference Ciliberto13, Thm. 4.4]). In particular, if $C/S$ is the universal family of (smooth) plane curves of degree d, then $\delta(C/S)=d$ (see [Reference Ciliberto13, Thm. 4.2]).

    • If $C/S$ is the universal family of hyperplanes sections of the universal family of polarized genus $g\geq 3$ K3 surfaces, then $\delta(C/S)=2g-2$ (see [Reference Ciliberto13, Prop. 4.5]).

    • If $C/S$ is the universal family of one of the following:

      • - the unique component with general moduli of the Hilbert scheme of curves in ${\mathbb P}^r$ with $r\geq 3$ of genus g and degree d;

      • - the Severi variety of curves of genus g together with a birational embedding as a nodal plane curve of degree d;

      • - the Hurwtiz scheme of degree d covers of ${\mathbb P}^1$ of genus g;

      and we assume that $\rho:=g-(r+1)(g+r-d)\geq 2$, then $\delta(C/S)=\gcd\{2g-2,d\}$ (see [Reference Ciliberto14, Thm. 1.1] and [Reference Ciliberto13, Thm. 5.3]).

    • If $C/S$ is the universal family of hyperelliptic genus g curves, then (see [Reference Mestrano and Ramanan35, Thm. 3.5])

      \begin{align*} \delta(C/S)= \begin{cases} 4 & \text{if }g \: \text{is odd, }\\ 2 & \: \text{if }g \: \text{is even.} \end{cases} \end{align*}

  4. (4) If $C/S$ is a family of curves of genus g = 0, then

    \begin{align*} \delta(C/S)= \begin{cases} 1 & \text{if }C/S \text{ is Zariski-locally trivial, }\\ 2 & \text{if }C/S \text{ is not Zariski-locally trivial.}\\ \end{cases} \end{align*}

    Note also that $C/S$ is Zariski locally trivial if and only if $C/S$ admits a section.

We will denote by $\operatorname{Pic}_{C/S}$ the relative Picard functor of the family CS, which is an algebraic stack representable and locally of finite presentation over S (by Artin’s representability theorem, see e.g. [Reference Bosch, Lütkebohmert and Raynaud10, § 8.3]). We have an exact sequence (see [Reference Bosch, Lütkebohmert and Raynaud10, § 8.1, Prop. 4])

\begin{align*} 0\to \operatorname{Pic}(S)\xrightarrow{\pi^*} \operatorname{Pic}(C) \to \operatorname{Pic}_{C/S}(S)\to \operatorname{Br}(S)\xrightarrow{\pi^*} \operatorname{Br}(C), \end{align*}

where $\operatorname{Br}(-)=H^2(-,\operatorname{\mathbb{G}}_{m})$ denote the cohomological Brauer group. In particular, we get an injective homomorphism

(2.2)\begin{equation} \operatorname{RPic}(C/S):=\frac{\operatorname{Pic}(C)}{\operatorname{Pic}(S)} \hookrightarrow \operatorname{Pic}_{C/S}(S). \end{equation}

Several of our results are restricted to families such that the inclusion (2.2) is an equality, or equivalently such that the natural map $\operatorname{Pic}(C)\to \operatorname{Pic}_{C/S}(S)$ is surjective. In the next Remark, we describe several families where this assumption holds true.

Remark 2.3. The inclusion (2.2) is an equality in the following cases:

  1. (1) if $\pi:C\to S$ admits a section (because $\pi^*:\operatorname{Br}(S)\to \operatorname{Br}(C)$ is injective); in particular, if $C/S={\mathcal C}_{g,n}/{\mathcal M}_{g,n}$ with n > 0. Therefore, equality in Equation (2.2) can always be achieved after an étale cover of the base S.

  2. (2) if $\operatorname{Br}(S)=0$, e.g. if S is the spectrum of a field $k=\overline k$, or the spectrum of strictly henselian valuation ring, or a smooth curve over $k=\overline k$.

  3. (3) if $C/S={\mathcal C}_{g}/{\mathcal M}_{g}$ and $g\geq 2$ by the strong Franchetta’s conjecture (see [Reference Mestrano34]).

  4. (4) if the relative Jacobian $J^d_{C/S}:=\operatorname{Pic}^d_{C/S}\to S$ in degree d admits a Poincaré line bundle for every $d\in\mathbb Z$.

  5. (5) if $\delta(C/S)=1$ (see [Reference Mestrano and Ramanan35, Lemma 2.2]).

Several of our results are restricted to families of curves $\pi: C\to S$ over an integral base S, which satisfy the following condition:

(2.3)\begin{equation}\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}, \end{equation}

where $\overline \eta$ is a geometric generic point of S.

In the next result, we collect some sufficient and necessary conditions for Equation (2.3) to hold.

Proposition 2.4. Let $\pi: C\to S$ a family of curves over an integral base S (locally of finite type over $k=\overline k$) and let $\overline \eta\to S$ be a geometric generic point.

  1. (1) If $\operatorname{End}(J_{C_{s}})={\mathbb Z}$ for some $s\in S(k)$, then $\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}$.

  2. (2) If k is uncountable and $\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}$, then $\operatorname{End}(J_{C_{s}})={\mathbb Z}$ for s very general in S(k).

  3. (3) If $k\not\subseteq \overline{\mathbb{F}_p}$, then $\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}$ if and only if there exists $s\in S(\overline k)$ such that $\operatorname{End}(J_{C_{s}})={\mathbb Z}$.

Note that part (3) is false if $k=\overline k=\overline{\mathbb{F}_p}$, see [Reference Maulik and Poonen32, Rmk. 1.12].

Proof. Parts (1) and (2) follow from the well-known fact (see the proof of [Reference Maulik and Poonen32, Prop. 1.13]) that the jumping locus

\begin{align*} S(k)_{\mathrm{jump}}=\{s\in S(k)\: :\: \operatorname{End}(J_{C_{\overline \eta}})\hookrightarrow \operatorname{End}(J_{C_s}) \text{is an isomorphism}\} \end{align*}

is the set of k-points of a union of countably many proper substacks of S.

Part (3) follows from the non-trivial result (proved in [Reference Maulik and Poonen32], [Reference Christensen12], [Reference Ambrosi1]) that $S(k)_{\mathrm{jump}}\neq S(k)$ if $k\neq \overline{\mathbb{F}_p}$.

Remark 2.5.

  1. (1) The condition $\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}$ is known to hold for several general families of curves, e.g.

    • the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ over an arbitrary field $k=\overline k$ by [Reference Koizumi25];

    • the universal family of hyperelliptic curves over an arbitrary field $k=\overline k$ by [Reference Mori36, Thm. 6.5];

    • the family of smooth curves belonging to a linear system on a regular smooth projective surface if $k={\mathbb C}$ by [Reference Zariski45].

  2. (2) The condition $\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}$ implies that the Néron–Severi of $J_{C_{\overline \eta}}$ is equal to

    (2.4)\begin{equation} \operatorname{NS}(J_{C_{\overline \eta}})={\mathbb Z}\cdot [\Theta_{C_{\overline \eta}}], \end{equation}

    where $[\Theta_C]$ is the class of a theta divisor $J_{C_{\overline \eta}}$ (using the fact that $\operatorname{NS}(J_{C_{\overline \eta}})$ is the subgroup of $\operatorname{End}(J_{C_{\overline \eta}})$ consisting of elements that are invariant under the Rosari involution). But the viceversa is false, e.g. for an elliptic curve with complex multiplication.

    Pirola has shown in [Reference Pietro Pirola38] that condition (2.4) holds true for any family CS of genus g curves over $k={\mathbb C}$ such that the image of S in ${\mathcal M}_g$ via the modular map has codimension less than or equal to g − 2 (e.g. the universal families of k-gonal curves of genus $g\geq 2$ for any $k\geq 2$). It would be interesting to know if for such families also the stronger statement $\operatorname{End}(J_{C_{\overline \eta}})={\mathbb Z}$ holds true.

2.2. Reductive groups

A reductive group (over $k=\overline k$) is a smooth and connected linear algebraic group over k (i.e. a closed algebraic subgroup of $(\operatorname{GL}_n)_k$, or equivalently an affine group scheme of finite type over k), which does not contain non-trivial connected normal unipotent algebraic subgroups. To any reductive group G, we can associate a cross-like diagram of reductive groups

where

  • $\mathscr D(G):=[G,G]$ is the derived subgroup of G;

  • $G^{\mathrm{ab}}:=G/\mathscr D(G)$ is called the abelianization of G;

  • $\mathscr R(G)$ is the radical subgroup of G, which is equal (since G is reductive) to the connected component $\mathscr Z(G)^o$ of the centre $\mathscr Z(G)$ and

  • $G^{\mathrm{ss}}:=G/\mathscr R(G)$ is called the semisimplification of G.

In the above diagram, the horizontal and vertical lines are short exact sequences of reductive groups, the morphisms $\mathscr D(G)\twoheadrightarrow G^{\mathrm{ss}}$ and $\mathscr R(G)\twoheadrightarrow G^{\mathrm{ab}}$ are central isogenies of, respectively, semisimple groups and tori with the same kernel. Since the two semisimple groups $\mathscr D(G)$ and $G^{\mathrm{ss}}$ are isogenous, they share the same simply connected cover, which we will denote by $G^{\mathrm{sc}}$, and the same adjoint quotient, which we will denote by $G^{\mathrm{ad}}$.

Given a reductive group G over k, we will denote by TG a maximal torus of G and by BG the positive Borel subgroup of G containing TG. As usual, we denote by $\mathscr W_G:=N(T_G)/T_G$ its Weyl group.

Given a torus T, we will denote by $\Lambda(T):=\operatorname{Hom}(\operatorname{\mathbb{G}}_{m},T)$ its cocharacter lattice and by $\Lambda^*(T):=\operatorname{Hom}(T, \operatorname{\mathbb{G}}_{m})$ its character lattice. Note that these lattices are dual to each other via the bilinear map

\begin{align*} \begin{aligned} \Lambda^*(T)\times \Lambda(T) & \longrightarrow \operatorname{Hom}(\operatorname{\mathbb{G}}_{m},\operatorname{\mathbb{G}}_{m})={\mathbb Z},\\ (\chi,d)& \mapsto \chi\circ d:=\chi(d). \end{aligned} \end{align*}

The fundamental group of G is $\displaystyle \pi_1(G):=\frac{\Lambda(T_G)}{\Lambda_{\mathrm{coroots}}},$ where $\Lambda_{\mathrm{coroots}}$ is the sublattice of $\Lambda(T_G)$, which is generated by integral linear combinations of coroots. The vertical exact sequence in Equation (2.5) induces an exact sequence of finitely generated abelian groups

(2.6)\begin{equation} 0\to \pi_1(\mathscr D(G))\to \pi_1(G) \xrightarrow{\pi_1(\mathrm{ab})}\pi_1(G^{\mathrm{ab}})\to 0, \end{equation}

which identifies $ \pi_1(\mathscr D(G))$ with the torsion subgroup of $\pi_1(G)$ and $\pi_1(G^{\mathrm{ab}})$ with the torsion-free quotient of $\pi_1(G)$.

2.3. The stack of G-bundles on a family of curves

In this subsection, G will be a connected and smooth linear algebraic group over $k=\overline k$. Further restrictions on G, like reductiveness, will be specified when needed.

For any family of curves $\pi: C\to S$, we denote by $\operatorname{\mathrm{Bun}}_{G}(C/S)$ the moduli stack of G-bundles on C → S, i.e. the algebraic stack over S whose fibre over VS is the groupoid of G-bundles $E\to C_V:=C\times_S V$. By definition, we have a forgetful surjective morphism

(2.7)\begin{equation} \Phi_G=\Phi_{G}(C/S):\operatorname{\mathrm{Bun}}_G(C/S) \longrightarrow S. \end{equation}

The stack $\operatorname{\mathrm{Bun}}_G(C/S)$ comes equipped with a universal G-torsor ${\mathcal P}$ on the universal family $\widehat \pi: \operatorname{\mathrm{Bun}}_G(C/S)\times_S C\to \operatorname{\mathrm{Bun}}_G(C/S)$.

The stack $\operatorname{\mathrm{Bun}}_G(C/S)$ is functorial in S, i.e. for any VS, we have that

\begin{align*} \operatorname{\mathrm{Bun}}_G(C_V/V)=\operatorname{\mathrm{Bun}}_G(C/S)\times_S V. \end{align*}

In particular, the fibre of $\Phi_G(C/S):\Phi_G(C/S)\to S$ over a k-point $s\in S$ is the moduli stack $\operatorname{\mathrm{Bun}}_G(C_s)$ of G-bundles on the curve Cs.

In the special case where the family of curves is the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ over the moduli stack of n-pointed curves of genus g, we set

\begin{align*} \operatorname{\mathrm{Bun}}_{G,g,n}:=\operatorname{\mathrm{Bun}}_G({\mathcal C}_{g,n}/{\mathcal M}_{g,n}). \end{align*}

In particular, if the family CS has constant relative genus $g=g(C/S)$, then we have that

\begin{equation*} \operatorname{\mathrm{Bun}}_{G}(C/S)=S\times_{{\mathcal M}_{g}}\operatorname{\mathrm{Bun}}_{G,g}, \end{equation*}

with respect to the modular morphism $S\to {\mathcal M}_g$ associated to the family CS.

Any morphism of connected and smooth linear algebraic groups $\phi:G\to H$ determines a morphism of stacks over S

(2.8)\begin{equation} \begin{array}{lccc} \phi_\sharp=\phi_{\sharp}(C/S):&\operatorname{\mathrm{Bun}}_{G}(C/S)&\longrightarrow&\operatorname{\mathrm{Bun}}_{H}(C/S)\\ &\Big(E\to C_V\Big)&\longmapsto &\Big(\phi_{\sharp}(E):=E\times^{\phi,G}H=(E\times H)/G\to C_V\Big), \end{array} \end{equation}

where the (right) action of G on E × H is $(p,h).g:=(p.g,\phi(g)^{-1}h)$.

We collect in the following fact the geometric properties of $\operatorname{\mathrm{Bun}}_G(C/S)$ and of the forgetful morphism $\Phi_{G}(C/S)$.

Fact 2.6.

Let G be a connected and smooth linear algebraic group and let $\pi:C\to S$ be a family of curves.

  1. (1) The morphism $\Phi_{G}(C/S)$ is locally of finite presentation, smooth, with affine and finitely presented relative diagonal.

  2. (2) There is a functorial decomposition into a disjoint union

    (2.9)\begin{equation} \Phi_{G}(C/S): \coprod_{\delta\in \pi_1(G)} \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\stackrel{\Phi_{G}^{\delta}(C/S)}{\longrightarrow} S \end{equation}

    such that the morphism $\Phi_G^{\delta}(C/S): \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\to S$ has geometric integral fibres for every $\delta\in \pi_1(G)$.

  3. (3) If G is reductive, then for any $\delta\in\pi_1(G)$, the morphism $\Phi_G^{\delta}(C/S):\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to S$ is Stein, i.e. it is fpqc and cohomologically flat in degree zero (which means that the natural morphism $(\Phi_G^{\delta}(C/S)^{\sharp}:{\mathcal O}_S \to \Phi_G^{\delta}(C/S)_*({\mathcal O}_{\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)})$ is a universal isomorphism), and of relative dimension equal to $(g-1)\dim G$.

Proof. Part (1): see [Reference Fringuelli and Viviani21, Thm. 3.1] and the references therein. Part (2): see [Reference Fringuelli and Viviani21, Thm. 3.1.1, Cor. 3.1.2] and the references therein. Part (3): see [Reference Fringuelli and Viviani21, Thm. 3.1.3] and the proof of [Reference Fringuelli and Viviani21, Prop. 3.3.2].

Since the centre $\mathscr Z(G)$ of a reductive group G acts functorially on any G-bundle, we have that $\mathscr Z(G)$ sits functorially inside the automorphism group of any T-point $(C_T\to T, E)$ of $\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)$ for any $\delta\in \pi_1(G)$. Hence, we can form the rigidification

(2.10)\begin{equation} \nu_G^{\delta}=\nu_G^{\delta}(C/S):\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\to \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\textit{[\!]} \mathscr Z(G):=\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S), \end{equation}

which turns out to be a $\mathscr Z(G)$-gerbe, i.e. a gerbe banded by $\mathscr Z(G)$.

3. The Picard group of $\operatorname{\mathrm{Bun}}^{\delta}_G(C/S)$

We will assume throughout this section that:

  • $\quad \star \quad \pi:C\to S$ is a family of smooth curves of genus $g=g(C/S)$ over an integral and regular quotient stack S (locally of finite type over k). We will denote by $\overline \eta\to S$ a geometric generic point of S and by $C_{\overline \eta}:=C\times_S \overline \eta$ the corresponding geometric generic fibre.

The aim of this section is to study the Picard group of $\operatorname{\mathrm{Bun}}^{\delta}_G(C/S)$ for a reductive group G.

3.1. Recollection on $\operatorname{Pic} \operatorname{\mathrm{Bun}}^{\delta}_G(C/S)$

In this subsection, we recall some facts from [Reference Fringuelli and Viviani21, Reference Fringuelli and Viviani22] on the Picard group of $\operatorname{\mathrm{Bun}}^{\delta}_G(C/S)$, for a reductive group G and a fixed $\delta\in \pi_1(G)$. The case g = 0 is slightly different from the other cases, and for unifying the statements, we need the following definition:

Definition-Lemma 3.1. Let G be a reductive group and pick a maximal torus $\iota:T_G\hookrightarrow G$.

  1. (1) We say that a cocharacter $d\in\Lambda(T_G)$ is generic if its image $d^{\mathrm{ss}}\in\Lambda(T_{G^\mathrm{ss}})\subset \Lambda(T_{G^\mathrm{ad}})$, into the cocharacter lattice of the adjoint group, satisfies one of the following equivalent conditions (see [Reference Fringuelli and Viviani21, Lemma 2.2.3]):

    1. (i) The contraction homomorphism

      \begin{align*} (d^{\mathrm{ss}},-): \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}=\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{G^\mathrm{sc}}))^{\mathscr W_G}& \to \Lambda^*(T_{G^\mathrm{sc}})\\ b & \mapsto b(d^\mathrm{ss},-) \end{align*}

      is injective.

    2. (ii) Let $G^{\mathrm{ad}}=G_1^{\mathrm{ad}}\times \ldots \times G_s^{\mathrm{ad}}$ be the decomposition of $G^{\mathrm{ad}}$ into almost simple factors (which are then automatically semisimple adjoint groups) and choose maximal tori in such a way that $T_{G^{\mathrm{ad}}}=T_{G_1^{\mathrm{ad}}}\times \ldots \times T_{G_s^{\mathrm{ad}}}$. Then, d ss satisfies the following condition:

      \begin{equation*} d^{ss}=d_1+\ldots+d_s\in \Lambda(T_{G^{\mathrm{ad}}})= \Lambda(T_{G_1^{\mathrm{ad}}})\oplus \ldots \oplus \Lambda(T_{G_s^{\mathrm{ad}}}), \end{equation*}

      with $d_i\neq 0$ for every $1\leq i \leq s$.

  2. (2) Any $\delta\in \pi_1(G)$ admits a lift $d\in \pi_1(T_G)=\Lambda(T_G)$, which is generic.

We collect in the following Fact the main results proved in [Reference Fringuelli and Viviani21] for the Picard group of $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$.

Fact 3.2.

Let G be a reductive group and fix $\delta\in\pi_1(G)$.

  1. (1) There exists an exact sequence

    \begin{align*} 0\to \operatorname{Pic}(S) \to \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C_{\overline \eta}), \end{align*}

    where the first map is the pull-back map and the second one is the restriction to the fibre of CS over a geometric generic point $\overline \eta$ of S.

  2. (2) For any lift $d\in\pi_1(B_G)=\pi_1(T_G)=\Lambda(T_G)$ of δ (which is moreover generic if g = 0), the pull-back maps along the inclusions $\iota:T_G\hookrightarrow B_G \hookrightarrow G$

    \begin{align*}\iota_\sharp^*:\operatorname{Pic} \operatorname{\mathrm{Bun}}^{\delta}_G(C/S)\hookrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}^d_{B_G}(C/S)\xrightarrow{\cong} \operatorname{Pic} \operatorname{\mathrm{Bun}}^d_{T_G}(C/S)\end{align*}

    are such that the first map is injective and the second one is an isomorphism.

  3. (3) There exists a unique homomorphism (called transgression map)

    (3.1)\begin{equation} \tau_G^{\delta}=\tau^{\delta}_G(C/S):(\operatorname{Sym}^2 \Lambda^*(T_G))^{\mathscr W_G}\hookrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \end{equation}

    that is functorial in S and G and fits in the following commutative diagram for any lift $d\in \pi_1(T_G)$ (which is generic if g = 0) of $\delta\in \pi_1(G)$:

    where $\langle -,-\rangle_{\pi}$ is the Deligne pairing of the family $\widehat \pi:C\times_S \operatorname{\mathrm{Bun}}_{T_G}^d(C/S)\times\operatorname{\mathrm{Bun}}_{T_G}^d(C/S) $ and ${\mathcal L}_{\chi}$ is the pull-back of the universal $\operatorname{\mathbb{G}}_{m}$-bundle (i.e. line bundle) over $C\times_S \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}(C/S)$ via the morphism $\operatorname{id} \times \chi_\#:C\times_S \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to C\times_S \operatorname{\mathrm{Bun}}^{(\delta,\chi)}_{\operatorname{\mathbb{G}}_{m}}(C/S)$.

Proof. Part (1) follows from [Reference Fringuelli and Viviani21, Prop. 5.1.1]. Part (2) follows from [Reference Fringuelli and Viviani21, Cor. 5.1.2, Thm. 6.0.1]. Part (3) follows from [Reference Fringuelli and Viviani21, Thm. 5.0.1, Rmk. 5.2.2] (whose proof works also for g = 0).

Using Fact 3.2(1), we will often restrict to study the relative Picard group

(3.3)\begin{equation} \operatorname{RPic} \operatorname{\mathrm{Bun}}_G^\delta(C/S):=\frac{\operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)}{\operatorname{Pic}(S)}. \end{equation}

3.2. The Picard group of $\operatorname{\mathrm{Bun}}^d_T(C/S)$ for a torus T

The goal of this subsection is to determine the structure of the Picard group of $\operatorname{\mathrm{Bun}}^{d}_T(C/S)$, where

  • $\quad \star \quad T$ is a torus and $d\in \Lambda(T)$.

We first introduce some natural line bundles on $\operatorname{\mathrm{Bun}}_T^d(C/S)$. For any character $\chi \in \Lambda^*(T)$ and $M\in \operatorname{Pic}(C)$, we consider the following line bundle on $C\times_S \operatorname{\mathrm{Bun}}_T^d(C/S)$:

\begin{align*} {\mathcal L}_{\chi}(M):={\mathcal L}_{\chi}\otimes p_1^*M, \end{align*}

where p 1 is the projection onto the first factor and ${\mathcal L}_{\chi}$ is the pull-back of the universal $\operatorname{\mathbb{G}}_{m}$-bundle (i.e. line bundle) over $C\times_S \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}(C/S)$ via the morphism $\operatorname{id}\times \chi_\#:C\times_S \operatorname{\mathrm{Bun}}_T^{d}(C/S)\to C\times_S \operatorname{\mathrm{Bun}}^{(d,\chi)}_{\operatorname{\mathbb{G}}_{m}}(C/S)$ induced by χ.

Definition 3.3. The tautological Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ is the subgroup $\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S)$ of $\operatorname{Pic}\operatorname{\mathrm{Bun}}_T^d(C/S)$ generated by the pull-back of the line bundles on S and the following line bundles (called tautological line bundles):

\begin{align*} \left\{d_{\widehat \pi}({\mathcal L}_{\chi}(M))\: : \chi\in \Lambda^*(T), M\in \operatorname{Pic}(C)\right\}, \end{align*}

where $d_{\widehat \pi}$ denotes the determinant of cohomology with respect to the family $\widehat \pi:C\times_S \operatorname{\mathrm{Bun}}_T^d(C/S)\to \operatorname{\mathrm{Bun}}_T^d(C/S)$.

The relative tautological Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ is the subgroup $\operatorname{RPic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S)\subseteq \operatorname{RPic} \operatorname{\mathrm{Bun}}_T^d(C/S)$, which is the image of $\operatorname{Pic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_T^d(C/S)$ into the relative Picard group.

Remark 3.4. The tautological Picard group $\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S)$ contains all the line bundles

\begin{align*} \left\{\langle {\mathcal L}_{\chi}(M),{\mathcal L}_{\mu}(N)\rangle_{\widehat \pi}: \chi,\mu\in \Lambda^*(T), M,N\in \operatorname{Pic}(C) \right\}, \end{align*}

where $\langle - , - \rangle_{\widehat \pi}$ is the Deligne pairing, since we have the following isomorphism:

(3.4)\begin{equation} \langle {\mathcal L}_{\chi}(M),{\mathcal L}_{\mu}(N)\rangle_{\widehat \pi}\cong d_{\widehat \pi}({\mathcal L}_{\chi+\mu}(M\otimes N))\otimes d_{\widehat \pi}({\mathcal L}_{\chi}(M))^{-1}\otimes d_{\widehat \pi}({\mathcal L}_{\mu}(N))^{-1}\otimes d_{\widehat \pi}({\mathcal O}). \end{equation}

The Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ is endowed with a weight function

(3.5)\begin{equation} \operatorname{Pic} \operatorname{\mathrm{Bun}}_T^d(C/S)\xrightarrow{w_T^{d}}\Lambda^*(T), \end{equation}

which is defined as it follows. Let $\mathcal F$ be a line bundle on $\operatorname{\mathrm{Bun}}_T^d(C/S))$ and fix a k-point $\xi:=(C_s, E)$ of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ over $s\in S$. The automorphism group of ξ acts on the fibre $\mathcal F_{\xi}$ of $\mathcal F$ over ξ. Since the torus T is contained in the automorphism group of ξ, this defines an action of T on $\mathcal F_{\xi}\cong k$, which is given by a character of T. This character, which is independent of the chosen k-point ξ and on the chosen isomorphism $\mathcal F_{\xi}\cong k$, coincides with $w_T^d(\mathcal F)$. Note that $w_T^d$ factors through the relative Picard group.

The weight function on the tautological Picard group is easily described.

Lemma 3.5. The weight function $w_T^d$ is given on tautological line bundles by

(3.6)\begin{equation} w_T^d(d_{\widehat \pi}({\mathcal L}_{\chi}(M)))=[\chi(d)+\deg_\pi(M)+1-g]\chi. \end{equation}

In particular, we have that

(3.7)\begin{equation} w_T^d(\langle {\mathcal L}_{\chi}(M),{\mathcal L}_{\mu}(N)\rangle_{\widehat \pi})=[\mu(d)+\deg_\pi(N)]\chi+[\chi(d)+\deg_\pi(M)]\mu. \end{equation}

Proof. This is proved as in [Reference Fringuelli and Viviani21, Prop. 4.1.2(1)].

Using the weight function, we can now describe the structure of the Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ for a family of curves of genus 0.

Theorem 3.6 Assume that $g(C/S)=0$. Then,

  1. (1) $\operatorname{Pic} \operatorname{\mathrm{Bun}}_T^d(C/S)=\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S)$.

  2. (2) the weight function

    \begin{align*} w_T^d: \operatorname{RPic} \operatorname{\mathrm{Bun}}_T^d(C/S)\hookrightarrow \Lambda^*(T) \end{align*}

    is injective on the relative Picard group.

  3. (3) The image of $w_T^d$ is equal to

    \begin{align*} \text{Im}(w_T^d)= \begin{cases} \Lambda^*(T) & \text{if } C/S \text{is Zariski-locally trivial},\\ \{\chi \in \Lambda^*(T)\: : \chi(d) \: \text{is even}\} & \text{if } C/S \text{is not Zariski-locally trivial.}\ \end{cases} \end{align*}

The above Theorem was proved for the universal family ${\mathcal C}_{0,n}\to {\mathcal M}_{0,n}$ (which is Zariski-locally trivial if and only if n > 0, see Remark 2.2) in [Reference Fringuelli and Viviani21, Thm. 4.2].

Proof. Part (2): since $g(C/S)=0$, the rigidification $\operatorname{\mathrm{Bun}}_T^d(C/S)\textit{[\!]} T$ is isomorphic to S. Hence, the Leray spectral sequence for $\operatorname{\mathbb{G}}_{m}$ associated to the T-gerbe $\operatorname{\mathrm{Bun}}_T^d(C/S)\to \operatorname{\mathrm{Bun}}_T^d(C/S)\textit{[\!]} T$ gives the desired exact sequence

\begin{align*} 0\to \operatorname{Pic}(S)=\operatorname{Pic}(\operatorname{\mathrm{Bun}}_T^d(C/S)\textit{[\!]} T) \to \operatorname{Pic} \operatorname{\mathrm{Bun}}_T^d(C/S)\xrightarrow{w_T^d} \operatorname{Pic}(BT)=\Lambda^*(T). \end{align*}

Note that $\delta(C/S)=1$ or 2 according to whether $C/S$ is Zariski-locally trivial or not (see Remark 2.2(4)). Hence, using the above exact sequence, in order to prove parts (1) and (3), it is enough to prove the two equalities

(3.8)\begin{equation} w_T^d(\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S))=\text{Im}(w_T^d)= \begin{cases} \Lambda^*(T) & \text{if } \delta(C/S)=1,\\ \{\chi \in \Lambda^*(T)\: : \chi(d) \: \text{is even}\} & \text{if } \delta(C/S)=2. \end{cases} \end{equation}

We will distinguish two cases.

Case 1: $\delta(C/S)=1$.

In this case, the relative degree map (2.1) is an isomorphism. Hence, given any $\chi\in \Lambda^*(T)$, we can choose a line bundle $M_{\chi}\in \operatorname{Pic}(C)$ having relative degree equal to $g-\chi(d)$, and then formula (3.6) implies that

\begin{align*} w_T^d(d_{\widehat \pi}({\mathcal L}_{\chi}(M_{\chi})))=\chi. \end{align*}

This shows that

\begin{align*} w_T^d(\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S))=\Lambda^*(T), \end{align*}

which gives the desired two equalities in Equation (3.8).

Case 2: $\delta(C/S)=2$.

In this case, the image of the relative degree map (2.1) is the subgroup $2{\mathbb Z}\subset {\mathbb Z}$. We will divide the proof of the equalities in Equation (3.8) into three steps.

$\bullet$ $w_T^d(\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S))\subseteq \{\chi \in \Lambda^*(T)\: : \chi(d) \: \text{is even}\}$.

To prove this, since $\operatorname{Pic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_T^d(C/S)$ is generated the tautological line bundles $d_{\widehat \pi}({\mathcal L}_{\chi}(M))$, it is enough to show, using formula 3.6, that

\begin{align*} d_{\widehat \pi}({\mathcal L}_{\chi}(M))(d)=[\chi(d)+\deg_{\pi}(M)+1]\chi(d)\: \text{is even} \end{align*}

for any $\chi\in \Lambda^*(T)$ and any $M\in \operatorname{Pic}(C)$. This is obvious if $\chi(d)$ is even. Otherwise, if $\chi(d)$ is odd, then it follows from the fact that $\chi(d)+\deg_{\pi}(M)+1$ is even because $\deg_{\pi}(M)$ is even.

$\bullet$ $w_T^d(\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S))\supseteq \{\chi \in \Lambda^*(T)\: : \chi(d) \: \text{is even}\}$.

Let $\chi\in \Lambda^*(T)$ such that $\chi(d)$ is even. Then, we can choice a line bundle $M_{\chi}\in \operatorname{Pic}(C)$ such that $\deg_{\pi}(M_{\chi})=-\chi(d)$. We then have, using formula (3.6), that

\begin{align*} d_{\widehat \pi}({\mathcal L}_{\chi}(M_{\chi}))=[\chi(d)+\deg_{\pi}(M_{\chi})+1]\chi=\chi, \end{align*}

which shows that $\chi \in w_T^d(\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S))$.

$\bullet$ $\text{Im}(w_T^d)\subseteq \{\chi \in \Lambda^*(T)\: : \chi(d) \: \text{is even}\}$.

Let L be a line bundle on $\operatorname{\mathrm{Bun}}_T^d(C/S)$ and set $\chi:=w_T^d(L)\in \Lambda^*(T)$. We want to show that $\chi(d)$ is even. Consider the following Cartesian diagram

The pull-back $\pi_T^*(L)$ on $\operatorname{\mathrm{Bun}}_T^d(C\times_S C/C)$ verifies $w_T^d(\pi_T^*(L))=\chi$, since the weight function is functorial with respect to base change. Consider now the line bundle $\langle {\mathcal L}_{\chi}, {\mathcal L}_0({\mathcal O}(\Delta))\rangle_{\widehat{\pi_2}}=\langle{\mathcal L}_{\chi}, {\mathcal O}(\widetilde \Delta)\rangle_{\widehat{\pi_2}}$ on $\operatorname{\mathrm{Bun}}_T^d(C\times_S C/C)$. By Equation (3.7) and the fact that $ {\mathcal O}(\Delta)$ has π 2-relative degree equal to 1, we have that

\begin{align*} w_T^d(\langle {\mathcal L}_{\chi}, {\mathcal O}(\widetilde \Delta)\rangle_{\widehat{\pi_2}})=\chi. \end{align*}

Therefore, since $\pi_T^*(L)$ and $\langle {\mathcal L}_{\chi}, {\mathcal O}(\widetilde \Delta)\rangle_{\widehat{\pi_2}}$ have the same weight, part (2) implies that

\begin{align*} \pi_T^*(L)=\langle {\mathcal L}_{\chi}, {\mathcal O}(\widetilde \Delta)\rangle_{\widehat{\pi_2}}\otimes \Phi_C^*(M) \end{align*}

for some $M\in \operatorname{Pic}(C)$. Taking the relative degree with respect to πT, we obtain that

\begin{align*} 0&=\deg_{\pi_T}(\pi_T^*(L))=\deg_{\pi_T}(\langle {\mathcal L}_{\chi}, {\mathcal O}(\widetilde \Delta)\rangle_{\widehat{\pi_2}})+\deg_{\pi_T}(\Phi_C^*(M)) =\\ &=\deg_{\pi_T}\widetilde \Delta^*({\mathcal L}_{\chi})+\deg_{\pi}(M)=\chi(d)+\deg_{\pi}(M), \end{align*}

where we have used the isomorphism $\langle {\mathcal L}_{\chi}, {\mathcal O}(\widetilde \Delta)\rangle_{\widehat{\pi_2}}\cong \widetilde \Delta^*({\mathcal L}_{\chi})$ has πT-relative degree equal to $\chi(d)$. This implies that $\chi(d)$ is even since $\deg_{\pi}(M)$ is even because of the hypothesis that $\delta(C/S)=2$.

We will now focus on families of curves of positive genus. In this case, the relative tautological Picard group is endowed with the following homomorphism:

Lemma 3.7. Assume that $g(C/S) \gt 0$. There exists a homomorphism

\begin{align*} \begin{aligned} \gamma_T^d:\operatorname{RPic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_T^d(C/S)& \longrightarrow \operatorname{Bil}^s \Lambda(T)=(\Lambda^*(T)\otimes \Lambda^*(T))^s,\\ d_{\widehat \pi}({\mathcal L}_{\chi}(M)) & \mapsto \chi\otimes \chi. \end{aligned} \end{align*}

In particular, we have that

\begin{align*} \gamma_T^d(\langle {\mathcal L}_{\chi}(M),{\mathcal L}_{\mu}(N)\rangle_{\widehat \pi})=\chi\otimes \mu+\mu\otimes \chi. \end{align*}

Proof. This is proved as in [Reference Fringuelli and Viviani21, Prop. 4.1.2(2)] (see also [Reference Fringuelli and Viviani22, Def./Lemma 3.5(2)]).

Using the above homomorphism $\gamma_T^d$, we can now describe the (relative) tautological Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ for families of curves of positive genus.

Theorem 3.8. Assume that $g=g(C/S) \gt 0$.

  1. (1) Then there exists a commutative diagram with exact rows, functorial in S and T

    where

    • $\operatorname{RPic}(C/S)$ is the relative Picard group of $C/S$ and $\operatorname{RPic}^0(C/S)$ is the subgroup consisting of line bundles of relative degree 0;

    • $i_T^d$ is defined by

      \begin{align*}i_T^d(\chi\otimes M)=\langle {\mathcal L}_{\chi}, M\rangle_{\widehat \pi};\end{align*}
    • $j_T^d$ is the restriction of $i_T^d$ to $\Lambda^*(T)\otimes \operatorname{RPic}^0(C/S)$;

    • $\tau_T^d$ is the transgression map (see Fact 3.2(3));

    • $\gamma_T^d$ is the map of Lemma 3.7;

    • $\rho_T^d$ is defined by

      \begin{align*} \rho_T^d(d_{\widehat \pi}({\mathcal L}_{\chi}(M)))(x)=\chi(x)^2 \mod 2; \end{align*}
    • ϵ is defined by

      \begin{align*} \epsilon(b)(x):=b(x,x) \mod 2. \end{align*}

  2. (2) The image of $w_T^d\oplus \gamma_T^d$ is equal to

    \begin{align*} \left\{(\chi, b)\in \Lambda^*(T)\oplus \operatorname{Bil}^s(\Lambda(T))\right.\:& : \: \delta(C/S)\vert \chi(x)-b(d,x)+(g-1)b(x,x) \\ &\left.\text{for every } x\in \Lambda(T)\right\}. \end{align*}

Most of the results of the previous theorem were known for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ with $g\geq 1$: the exactness of the first line in Equation (3.10) and part (2) were proved in [Reference Fringuelli and Viviani21, Prop. 4.3.1]; the exactness of the second line in Equation (3.10) was proved in [Reference Fringuelli and Viviani22, Thm. 3.6] (where it is also proved for an arbitrary reductive group); the exactness of the third line in Equation (3.10) was proved for g = 1 in [Reference Fringuelli and Viviani21, Thm. B] (while for genus $g\geq 2$, a different presentation is obtained in loc. cit.).

Proof. Let us first prove part (1). Observe that the diagram is commutative: the commutativity of the two left squares and he upper right square are obvious; the commutativity of the lower right square follows from the fact that $(\chi\otimes \chi)(x,y)=\chi(x)\chi(y)$.

We now divide the rest of the proof of part (1) into three steps.

Step 1: The middle row is exact.

First of all, observe that $i_T^d$ is well-defined since the Deligne pairing $\langle-,-\rangle_{\widehat \pi}$ is bilinear and it is trivial on the pull-back of line bundle on $\operatorname{\mathrm{Bun}}_T^d(C/S)$, and hence in particular on those coming from S. Consider now the following diagram

where the vertical maps are restriction maps to the geometric generic fibre $C_{\overline \eta}$ of $C/S$ and the map $i_T^d(C_{\overline \eta})$ is the restriction of $i_T^d$ to the the geometric generic fibre. Since the restriction maps are injective by Fact 3.2(1) and [Reference Fringuelli and Viviani21, Prop. 2.3.2] and the map $i_T^d(C_{\overline \eta})$ is injective by [Reference Biswas and Hoffmann7, § 3], we deduce that $i_T^d$ is also injective.

Lemma 3.7 implies that $\text{Im}(i_T^d)\subseteq \ker(\gamma_T^d)$ and that $\gamma_T^d$ is surjective, using that $(\Lambda^*(T)\otimes \Lambda^*(T))^s$ is generated by the elements $\{\chi\otimes \chi\: : \chi\in \Lambda^*(T)\}$ (see [Reference Fringuelli and Viviani21, § 2.2]).

It remains to prove that $\ker(\gamma_T^d)\subseteq \text{Im}(i_T^d)$. To this aim, we fix a basis $\{\chi_1,\ldots,\chi_r\}$ of $\Lambda^*(T)$. Then, $\operatorname{RPic}^{\operatorname{taut}}(\operatorname{\mathrm{Bun}}_T^d(C/S))$ is generated by the line bundles

\begin{align*} \{d_{\widehat \pi}({\mathcal L}_{\chi_i}), \langle {\mathcal L}_{\chi_j},{\mathcal L}_{\chi_k}\rangle_{\widehat \pi}, \langle {\mathcal L}_{\chi_h}, M\rangle_{\widehat \pi}\}, \end{align*}

with $1\leq i, h\leq r$, $1\leq j\leq k\leq r$ and $M\in \operatorname{RPic}(C/S)$. The line bundles $ \langle {\mathcal L}_{\chi_h}, M\rangle_{\widehat \pi}$ belong to $\text{Im}(i_T^d)\subseteq \ker(\gamma_T^d)$ as proved above. Suppose that we have a line bundle on $\operatorname{\mathrm{Bun}}_T^d(C/S)$

\begin{align*} K:=\bigotimes_i d_{\widehat \pi}({\mathcal L}_{\chi_i})^{a_i}\bigotimes_{j\leq k} \langle {\mathcal L}_{\chi_j},{\mathcal L}_{\chi_k}\rangle_{\widehat \pi}^{b_{jk}} \: \text{for some } a_i, b_{jk}\in {\mathbb Z} \end{align*}

whose class in the relative tautological Picard group belongs to $\ker(\gamma_T^d)$. Then, Lemma 3.7 implies that

(3.11)\begin{align} 0=\gamma_T^d\left(\bigotimes_i d_{\widehat \pi}({\mathcal L}_{\chi_i})^{a_i}\bigotimes_{j\leq k} \langle {\mathcal L}_{\chi_j},{\mathcal L}_{\chi_k}\rangle_{\widehat \pi}^{b_{jk}}\right)=\sum_i a_i \chi_i\otimes\chi_i+\sum_{j\leq k} b_{jk}(\chi_j\otimes \chi_k+\chi_k\otimes \chi_j).\nonumber\\ \end{align}

Since a basis of $\operatorname{Bil}^s(\Lambda(T))=(\Lambda^*(T)\otimes \Lambda^*(T))^s$ is given by $\{\{\chi_i\otimes \chi_i\}_i\cup \{\chi_j\otimes \chi_k+\chi_k\otimes \chi_j\}_{j \lt k}\}$, the relation Equation (3.11) is equivalent to

\begin{align*} \begin{cases} b_{jk}=0 & \text{for any }j \lt k,\\ a_i+2b_{ii}=0 & \text{for any }i. \end{cases} \end{align*}

Hence, the line bundle K is equal to

\begin{align*} K=\bigotimes_i [d_{\widehat \pi}({\mathcal L}_{\chi_i})^{-2}\bigotimes \langle {\mathcal L}_{\chi_i}, {\mathcal L}_{\chi_i}\rangle_{\widehat \pi}]^{b_{ii}}= \bigotimes_i [\langle {\mathcal L}_{\chi_i}, \omega_{\widehat \pi}\rangle_{\widehat \pi}\otimes d_{\widehat \pi}({\mathcal O})^{-2}]^{b_{ii}}, \end{align*}

where the last equality follows from [Reference Fringuelli and Viviani21, Rmk. 3.5.1]. This implies that the class of K in the relative Picard group belongs to $\text{Im}(i_T^d)$, and we are done.

Step 2: The first row is exact.

Indeed, the map $j_T^d$ is injective since it is the restriction of the injective map $i_T^d$. Using the exactness of the middle row, the kernel of $w_T^d\oplus \gamma_T^d$ is equal to

\begin{align*} \ker(w_T^d\oplus \gamma_T^d)=\left\{i_T^d(\chi\otimes M)\: : \: \operatorname{wt}_T^d(i_T^d(\chi\otimes M))=0\right\}. \end{align*}

By the definition of $i_T^d$ and Equation (3.7), we compute

\begin{align*} \operatorname{wt}_T^d(i_T^d(\chi\otimes M))=w_T^d(\langle {\mathcal L}_{\chi}, M\rangle_{\widehat \pi})=\deg_{\pi}(M)\chi. \end{align*}

Hence, the kernel of $w_T^d\oplus \gamma_T^d$ coincides with the image via $i_T^d$ (or equivalently via $j_T^d$) of $\Lambda^*(T)\otimes \operatorname{RPic}^0(C/S)$, and we are done.

Step 3: The last row is exact.

Indeed, the composition $\gamma_T^d\circ \tau_T^d$ is given by

\begin{align*} (\gamma_T^d\circ \tau_T^d)(\gamma\cdot \gamma^\prime)=\gamma_T^d(\langle {\mathcal L}_{\gamma}, {\mathcal L}_{\gamma^\prime}\rangle_{\widehat \pi})=\gamma\otimes \gamma^\prime+\gamma^\prime\otimes \gamma . \end{align*}

Hence, $\gamma_T^d\circ \tau_T^d$ is injective, and its image is the subgroup $\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T))\subset \operatorname{Bil}^s(\Lambda(T))$ of even symmetric bilinear forms (see [Reference Fringuelli and Viviani21, § 2.2]). We now deduce the exactness of the last row from the exactness of the second row and the fact that $\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T))$ is the kernel of the surjective map ϵ.

Let us prove now part (2). We first observe that the image of $w_T^d\oplus \gamma_T^d$ is contained in

\begin{align*} I:=\left\{(\chi, b)\in \Lambda^*(T)\oplus \operatorname{Bil}^s(\Lambda(T))\right.\:& : \: \delta(C/S)\vert \chi(x)-b(d,x)+(g-1)b(x,x) \\ &\left.\text{for every } x\in \Lambda(T)\right\}. \end{align*}

Indeed, for the generators of $\operatorname{RPic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d(C/S)$, we compute (using Equation (3.6) and Lemma 3.7) that

\begin{align*} (w_T^d,\gamma_T^d)(d_{\widehat \pi}({\mathcal L}_{\chi}(M)))=(\chi(d)+\deg_{\pi}(M)+1-g)\chi, \chi\otimes \chi). \end{align*}

Hence, for any $x\in \Lambda(T)$, we get

\begin{align*} [\chi(d)+\deg_{\pi}(M)+1-g] \chi(x) -\chi(d)\chi(x)+(g-1)\chi(x)^2&=[\deg_{\pi}(M)+1-g] \chi(x)\\&\quad +(g-1)\chi(x)^2=\\ =\deg_{\pi}(M) \chi(x) +(g-1)[\chi(x)^2-\chi(x)]& \equiv \deg_{\pi}(M) \chi(x) \mod 2g-2 \\ & \equiv 0 \mod \delta(C/S), \end{align*}

where in the last congruence relation we used the fact that $\deg_{\pi}(M) $ is a multiple of $\delta(C/S)$ (by definition of $\delta(C/S)$) and that $\delta(C/S)$ is a multiple of $2g-2$ (by Remark 2.2(1)).

Next, in order to show that the inclusion $\text{Im}(w_T^d\oplus \gamma_T^d)\subseteq I$ is an equality, we consider the following commutative diagram with exact vertical columns:

We now conclude using that

$\bullet$ $p_2(\text{Im}(w_T^d\oplus \gamma_T^d))=\operatorname{Bil}^s(\Lambda(T))$ as it follows from the right upper square of the diagram (3.10);

$\bullet$ the inclusion

\begin{align*}\text{Im}(w_T^d\oplus \gamma_T^d)\cap (\Lambda^*(T)\times \{0\}) \subseteq I \cap (\Lambda^*(T)\times \{0\})=\delta(C/S)\cdot \Lambda^*(T)\end{align*}

is an equality since it coincides with the boundary homomorphism coming from the snake lemma applied to the first two horizontal lines of the diagram (3.10).

After having obtained in Theorem 3.8, a complete description of the tautological Picard group of $\operatorname{\mathrm{Bun}}_T^d(C/S)$ for families of curves of positive genus, the next natural question is to determine when the entire Picard group coincides with the tautological subgroup. A sufficient condition is provided by the following:

Theorem 3.9 Assume that $g=g(C/S) \gt 0$. If $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ and $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$, then

\begin{align*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_T^d(C/S)=\operatorname{Pic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_T^d(C/S). \end{align*}

The above theorem was shown in [Reference Biswas and Hoffmann7] (see also [Reference Fringuelli and Viviani21, Prop. 4.1.1]) for a curve C over $S=\operatorname{Spec} k$, with k an algebraically closed field, in which case the second assumption is automatic and the first assumption $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ is also necessary for the theorem to hold. Theorem 3.9 recovers the equality $\operatorname{Pic}\operatorname{\mathrm{Bun}}_T^d({\mathcal C}_{g,n}/{\mathcal M}_{g,n})=\operatorname{Pic}^{\operatorname{taut}}\operatorname{\mathrm{Bun}}_T^d({\mathcal C}_{g,n}/{\mathcal M}_{g,n})$, which was shown in [Reference Fringuelli and Viviani21, Thm. 4.1] for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ (with $g\geq 1$), since the assumption of the Theorem is known to hold for ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ (see Remarks 2.3 and 2.5(1)).

Proof. We will distinguish three cases.

Case I: d = 0 and $\pi: C\to S$ admits a section σ.

Since d = 0, we have the canonical identifications

\begin{align*} \begin{cases} & \operatorname{\mathrm{Bun}}_T^0(C/S)= {\mathcal J}^0(C/S)\otimes \Lambda(T), \\ & \operatorname{\mathrm{Bun}}_T^0(C/S)\textit{[\!]} T=J^0(C/S)\otimes \Lambda(T),\\ \end{cases} \end{align*}

where ${\mathcal J}^0(C/S)$ is the Jacobian stack of $C/S$ and $J^0(C/S)={\mathcal J}^0(C/S)\textit{[\!]} T$ is the Jacobian scheme of $C/S$. The theorem is implied in this case by the following commutative diagram with exact rows:

where

  • the first line is exact by Theorem 3.8 using that $\delta(C/S)=1$ since $\pi: C\to S$ has a section by assumption;

  • the second exact line comes from the fact that the rigidification $\operatorname{\mathrm{Bun}}_T^0(C/S)\textit{[\!]} T=J^0(C/S)\otimes \Lambda(T)\to S$ is an abelian scheme (see e.g. the proof of [Reference Fringuelli and Pirisi19, Prop. 3.6]), where $(J^0(C/S)\otimes \Lambda(T))^{\vee}=J^0(C/S)^{\vee} \otimes \Lambda^*(T)$ is the dual abelian scheme and the last map is the restriction homomorphism onto the geometric generic fibre;

  • the left vertical isomorphism follows from the fact that $\operatorname{RPic}^0(C/S)=J^0(C/S)^{\vee}(S)$;

  • the right vertical isomorphism follows from the fact that (see [Reference Biswas and Hoffmann7, § 3.2])

    \begin{align*} \operatorname{NS}(\operatorname{\mathrm{Bun}}_T^0(C_{\overline \eta}))=\Lambda^*(T)\oplus \operatorname{Hom}^s(\Lambda(T)\otimes \Lambda(T), \operatorname{End}(J_{C_{\overline \eta}})), \end{align*}

    where $\operatorname{Hom}^s(\Lambda(T)\otimes \Lambda(T), \operatorname{End}(J_{C_{\overline \eta}}))$ is the set of bilinear forms $\operatorname{Hom}(\Lambda(T)\otimes \Lambda(T), \operatorname{End}(J_{C_{\overline \eta}}))$ that are symmetric with respect to the Rosati involution, together with the assumption that $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$.

  • the commutativity of the left square follows from the proof of [Reference Fringuelli and Viviani21, Lemma 4.2.1]Footnote 1 together with formula (3.4);

  • the commutativity of the right square follows from [Reference Fringuelli and Viviani21, Prop. 4.1.2]Footnote 2.

Case II: $\pi: C\to S$ admits a section σ.

Fix an isomorphism $T\cong \operatorname{\mathbb{G}}_{m}^r$, which induces a canonical isomorphism $\Lambda(T)\cong {\mathbb Z}^r$ under which d corresponds to $(d_1,\ldots, d_r)$. Then, we have an isomorphism

\begin{align*}\operatorname{\mathrm{Bun}}_T^d(C/S)\cong \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{d_1}(C/S)\times_S \ldots \times_S \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{d_r}(C/S).\end{align*}

Using the section σ, we define an isomorphism

\begin{align*} \begin{aligned} \mathfrak t: \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{d_1}(C/S)\times_S \ldots \times_S \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{d_r}(C/S) & \xrightarrow{\cong} \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{0}(C/S)\times_S \ldots \times_S \operatorname{\mathrm{Bun}}_{\operatorname{\mathbb{G}}_{m}}^{0}(C/S)\\ &\cong \operatorname{\mathrm{Bun}}^0_T(C/S)\\ (L_1,\ldots, L_r) & \mapsto (L_1(-d_1\sigma), \ldots, L_r(-d_r\sigma)). \end{aligned} \end{align*}

By construction, we have that $(\mathfrak t\times \operatorname{id})^*({\mathcal L}_{e_i})={\mathcal L}_{e_i}(-d_i\sigma)$, where $\{e_i\}$ is the canonical basis of ${\mathbb Z}^r\cong \Lambda^*(T)$. Hence, using the functoriality of the determinant of cohomology, we deduce that the pull-back isomorphism

\begin{align*}\mathfrak t^*:\operatorname{Pic} \operatorname{\mathrm{Bun}}^0_T(C/S)\xrightarrow{\cong} \operatorname{Pic}\operatorname{\mathrm{Bun}}_T^d(C/S)\end{align*}

preserves the tautological subgroups. Hence, the conclusion is implied by Case I.

Case III: General case.

Let $\pi: C\to S$ be an arbitrary family of curves (i.e. possibly without a section). Fix a smooth cover $S^\prime\to S$ such that the family $C^\prime:=C\times_SS^\prime\to S^\prime$ admits a section (e.g. CS). By Case II, we have the following morphism of exact sequences:

where $(C^{\prime\prime}\to S^{\prime\prime}):=(C^{\prime}\times_SS^{\prime}\to S^{\prime}\times_SS^{\prime})$ and $p_1,p_2:C^{\prime\prime}\to C^{\prime}$ denotes the natural projections.

Consider the following commutative diagram of abelian groups:

where all the rows are exact: the first one by Theorem 3.8, the second one by definition and the third one is obtained by taking the kernels of the vertical arrows in Diagram (3.13).

By applying the snake lemma at the first and the third rows, and using the assumption $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$, we deduce that the central vertical arrows in the middle must be equalities,and thus, we have the assertion.

Remark. If we remove the hypothesis $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$, Theorem 3.9 is false. Indeed, from the proof of Case III, we may deduce the following exact sequence of abstract groups:

\begin{align*} 0\to \Lambda^*(T)\otimes \operatorname{Pic}_{C/S}(C)\to \operatorname{Pic}_{\operatorname{\mathrm{Bun}}_T^d(C/S)/S}(S)\to \operatorname{Bil}^s(\Lambda(T))\to 0, \end{align*}

where $\operatorname{Pic}_{\operatorname{\mathrm{Bun}}_T^d(C/S)/S}$ denotes the relative Picard sheaf of the relative moduli stack $\operatorname{\mathrm{Bun}}_T^d(C/S)\to S$. If we assume $\operatorname{RPic}(C/S)\subsetneq\operatorname{Pic}_{C/S}(S)$ and $\operatorname{RPic}(\operatorname{\mathrm{Bun}}_T^d(C/S))= \operatorname{Pic}_{\operatorname{\mathrm{Bun}}_T^d(C/S)/S}(S)$ (e.g. if d = 0, because $\operatorname{\mathrm{Bun}}_T^0(C/S)\to S$ has sections), we get $\operatorname{RPic}^{\operatorname{taut}}(\operatorname{\mathrm{Bun}}_T^d(C/S))\subsetneq\operatorname{RPic}(\operatorname{\mathrm{Bun}}_T^d(C/S))$.

3.3. The Picard group of $\operatorname{\mathrm{Bun}}^{\delta}_G(C/S)$ for G reductive

In this subsection, we study when the Picard group of $\operatorname{\mathrm{Bun}}^{\delta}_G(C/S)$ is generated by the image of the pull-back along the abelianization map

\begin{align*} \mathrm{ab}_{\sharp}:\operatorname{\mathrm{Bun}}^{\delta}_G(C/S)\to \operatorname{\mathrm{Bun}}^{\delta^{\mathrm{ab}}}_{G^{\mathrm{ab}}}(C/S), \end{align*}

where $\delta^{\mathrm{ab}}:=\pi_1(\mathrm{ab})(\delta)$, and the image of the transgression map (3.1).

More precisely, we investigate when the following commutative diagram, which is functorial in G and S:

is a push-out diagram, where $\tau_G^{\delta}$ and $\tau_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}$ are, respectively, the transgression maps for G and $G^{\mathrm{ab}}$ (see Fact 3.2(3)), $\operatorname{Sym}^2 \Lambda_{\mathrm{ab}}^*$ is the injective homomorphism induced by the inclusion $\Lambda_{\mathrm{ab}}^*:\Lambda^*(G^{\mathrm{ab}})\hookrightarrow \Lambda^*(T_{G})$, which is invariant under the $\mathscr W_G$-action on $\Lambda^*(T_{G})$, and $\mathrm{ab}_{\sharp}^*$ is injective by the following:

Lemma 3.11. The pull-back map

\begin{align*} \mathrm{ab}_{\sharp}^*: \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\to \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \end{align*}

is injective.

Proof. The composition

\begin{align*}\phi:T_G\stackrel{\iota}{\hookrightarrow} G \stackrel{\mathrm{ab}}{\twoheadrightarrow} G^{\mathrm{ab}}\end{align*}

is a surjective homomorphism of tori, hence it admits a section. This implies that, for any lift $d\in \pi_1(T_G)$ of $\delta\in \pi_1(G)$, the homomorphism

\begin{align*} \phi_{\sharp}^*:\operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\xrightarrow{\mathrm{ab}_\sharp^*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \xrightarrow{\iota_\sharp^*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S) \end{align*}

is injective. Hence, also the homomorphism $\mathrm{ab}_{\sharp}^*$ must be injective.

We will use the following easy lemma on push-out diagrams of abelian groups.

Lemma 3.12. Consider a commutative diagram of abelian groups

where i and j are injective homomorphisms. Then Equation (3.15) is a push-out diagram if and only if the natural map $\operatorname{coker} i\to \operatorname{coker} j$ is an isomorphism.

Proof. This is easy and left to the reader.

Hence, the diagram (3.14) is a push-out diagram if and only if the induced homomorphism

\begin{align*} \operatorname{coker}(\operatorname{Sym}^2 \Lambda_{\mathrm{ab}}^*)\rightarrow \operatorname{coker}(\mathrm{ab}_{\sharp}^*) \end{align*}

is an isomorphism.

The cokernel of $\operatorname{Sym}^2 \Lambda_{\mathrm{ab}}^*$ is described explicitly as follows:

Lemma 3.13.

  1. (1) We have an exact sequence of lattices, functorial in G,

    (3.16)\begin{equation} \begin{aligned} & 0\to \operatorname{Sym}^2 \Lambda^*(G^{\mathrm{ab}}) \xrightarrow{\operatorname{Sym}^2\Lambda_{\mathrm{ab}}^*} \operatorname{Sym}^2\Lambda^*(T_G)^{\mathscr W_G} \xrightarrow{\operatorname{res}_{\mathscr D}} \operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G}\to 0,\\ & b \mapsto b_{|\Lambda(T_{\mathscr D(G)})\otimes \Lambda(T_{\mathscr D(G)})} \\ \end{aligned} \end{equation}

    where we identify $\operatorname{Sym}^2\Lambda^*(T_G)$ with the lattice $\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_G))$ of even symmetric bilinear forms and the last group is defined by

    \begin{align*} &\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G}\\ &\quad :=\left\{b\in \operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)}))^{\mathscr W_G}\: : \: b^{{\mathbb Q}}_{|\Lambda(T_{\mathscr D(G)})\otimes \Lambda(T_{G^{\mathrm{ss}}})}\: \text{is integral}\right\}, \end{align*}

    where $b^{{\mathbb Q}}$ is the extension of b to a rational bilinear symmetric form on $\Lambda(T_{G^{\mathrm{ss}}})$.

  2. (2) If $G^{\mathrm{sc}}\cong G_1\times \ldots \times G_s$ is the decomposition of the universal cover $G^{\mathrm{sc}}$ of $\mathscr D(G)$ into simply connected quasi-simple groups, then $\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G}$ is a finite index sub-lattice of

    \begin{align*} \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}=\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{G^{\mathrm{sc}}}))^{\mathscr W_G}={\mathbb Z}\langle b_1\rangle \oplus \ldots \oplus {\mathbb Z}\langle b_s\rangle, \end{align*}

    where bi is the basic inner product of Gi.

  3. (3) If $\mathscr D(G)$ is simply connected (i.e. $\mathscr D(G)=G^{\mathrm{sc}}$), then

    \begin{align*} \operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G}=\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{G^{\mathrm{sc}}}))^{\mathscr W_G}. \end{align*}

Proof. Part (1) is proved in [Reference Fringuelli and Viviani22, Prop. 2.4]. Part (2) follows from the fact that we have finite index inclusions of lattices

\begin{align*} \Lambda(T_{G^{\mathrm{sc}}})\hookrightarrow \Lambda(T_{\mathscr D(G)})\hookrightarrow \Lambda(T_{G^{\mathrm{ss}}}) \end{align*}

together with [Reference Fringuelli and Viviani21, Lemma 2.2.1]. Part (3) follows from [Reference Biswas and Hoffmann7, Lemma 4.3.4].

A first case where Equation (3.15) is a push-out diagram is provided by the following:

Theorem 3.14. Assume that G is a reductive group such that $\mathscr D(G)$ is simply connected and fix $\delta\in\pi_1(G)$. There exists an exact sequence functorial in S and G

(3.17)\begin{equation} 0\to \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\xrightarrow{\mathrm{ab}_\sharp^*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}\to 0 \end{equation}

together with a (non-canonical) splitting functorial in S.

In particular, the commutative diagram (3.15) is a push-out diagram.

This theorem was proved: for G semisimple by Faltings [Reference Faltings17], for a fixed curve C over $k=\overline k$ by Biswas–Hoffmann [Reference Biswas and Hoffmann7] and for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ for $g\geq 1$ by the authors in [Reference Fringuelli and Viviani21, Thm. C(2)] and [Reference Fringuelli and Viviani22, Cor. 3.4].

Proof. The second assertion follows from the first one using Lemmas 3.12 and 3.13, and the assumption that $\mathscr D(G)$ is simply connected. Hence, it is enough to prove the first assertion.

Let $\overline \eta$ be a geometric generic point of S. The family $\pi:C\to S$ sits in the following Cartesian diagram of families of curves:

The above diagram gives rise to the following commutative diagram with exact rows:

where

  • the first line is exact by [Reference Fringuelli and Viviani22, Cor. 3.4] for $g\geq 1$ and by Lemma 3.15 for g = 0, where $\operatorname{\mathrm{Bun}}^{\delta}_{G,g}:=\operatorname{\mathrm{Bun}}_G^{\delta}({\mathcal C}_g/{\mathcal M}_g)$ and similarly for $G^{\mathrm{ab}}$;

  • ${\mathcal Q}$ is the cokernel of $\mathrm{ab}_\sharp^*(C/S)$, so that the second line is exact by definition;

  • the third line is exact as it follows by applying [Reference Biswas and Hoffmann7, Thm. 5.3.1] to the morphism $\mathrm{ab}$ and using [Reference Biswas and Hoffmann7, Prop. 5.2.11] together with our hypothesis that $\mathscr D(G)$ is simple connected;

  • the vertical morphisms in the left and central columns are injective by Fact 3.2(1);

  • the composition $\sigma\circ \rho$ is the identity, which implies that ρ is injective and σ is surjective.

It remains to show that σ is injective (or, equivalently, that ρ is surjective), and that the exact sequence Equation (3.17) admits a functorial splitting.

To this aim, consider the surjective morphisms of tori $T_G\hookrightarrow G\xrightarrow{\mathrm{ab}} G^{\mathrm{ab}}$ and pick a section $\widetilde \iota: G^{\mathrm{ab}}\hookrightarrow T_G$. The composition $\iota: G^{\mathrm{ab}}\stackrel{\widetilde \iota}{\hookrightarrow} T_G\hookrightarrow G$ is a section of $\mathrm{ab}$. The induced morphism

\begin{align*}\iota_{\sharp}(C/S):\operatorname{\mathrm{Bun}}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\hookrightarrow \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\end{align*}

is a section of the morphism $\mathrm{ab}_{\sharp}(C/S)$. By taking the pull-back at the level of the Picard groups, we deduce that the inclusion

\begin{align*} \mathrm{ab}_{\sharp}^*(C/S): \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\hookrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \end{align*}

admits a splitting, which is functorial in S, namely

\begin{align*}\iota_{\sharp}(C/S)^*: \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\twoheadrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S).\end{align*}

This shows that the exact rows in Equation (3.15) admit compatible splittings, which implies that σ is injective, and we are done.

The following lemma extends [Reference Fringuelli and Viviani22, Cor. 3.4] to genus zero, for the reductive groups with simply connected derived subgroup.

Lemma 3.15. Let G be a reductive group such that $\mathscr D(G)$ is simply connected. For every $n\geq 0$, there exists an exact sequence, functorial in G

(3.19)\begin{equation} 0\to \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}},0, n}^{\delta^{\mathrm{ab}}}\xrightarrow{\mathrm{ab}_\sharp^*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G,0, n}^{\delta}\to \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}\to 0. \end{equation}

Proof. We will use the notation and results from [Reference Fringuelli and Viviani21, § 5]. Since the map $\pi_1(\mathrm{ab}):\pi_1(G)\xrightarrow{\cong} \pi_1(G^{\mathrm{ab}})=\Lambda(G^{\mathrm{ab}})$ is an isomorphism by the hypothesis that $\mathscr D(G)$ is simply connected (see Equation (2.6)), we can pick a lift $d\in \Lambda(T_G)$ of $\delta\in \pi_1(G)$, which is generic (see Definition/Lemma 3.1) and such that the following condition holds:

(*)\begin{equation} \delta^{\mathrm{ab}} \text{is 2-divisible in }\Lambda(G^{\mathrm{ab}}) \Longrightarrow d \text{is 2-divisible in }\Lambda(T_G). \end{equation}

By [Reference Fringuelli and Viviani21, Thm. 5.2], there exists a commutative diagram

where $\iota:T_G\hookrightarrow G$.

By the definition of $\Omega_d(T_G)$ and the fact that d is generic (see Definition/Lemma 3.1), the contraction homomorphism defines an isomorphism

(3.21)\begin{equation} \begin{aligned} (d^{\mathrm{ss}},-): \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G} & \stackrel{\cong}{\longrightarrow} \frac{\Omega_d(T_G)}{\Lambda^*(G^{\mathrm{ab}})} \subseteq \frac{\Lambda^*(T_G)}{\Lambda^*(G^{\mathrm{ab}})}=\Lambda^*(T_{G^{\mathrm{sc}}}), \\ b &\mapsto b(d^{\mathrm{ss}}, -). \end{aligned} \end{equation}

Now, if $n\geq 1$, then the maps $\omega_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}$ and $\omega_G^{\delta}$ are isomorphisms by [Reference Fringuelli and Viviani21, Thm. 5.2(2)], and we conclude by putting together Equations (3.20) and (3.21). On the other hand, if n = 0, then [Reference Fringuelli and Viviani21, Thm. 5.2(2)] gives that

(3.22)\begin{equation} \begin{cases} & \text{Im}(\omega_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})=\{\chi \in \Lambda^*(G^{\mathrm{ab}})\: : \: \chi(\delta^{\mathrm{ab}})\in 2{\mathbb Z}\}, \\ & \text{Im}(\omega_{G}^{\delta})=\{\chi \in \Omega^*_d(T_G)\: : \: \chi(d)\in 2{\mathbb Z}\}. \\ \end{cases} \end{equation}

This implies that the commutative diagram of abelian groups is a pull-back diagram

since if $\chi \in \Lambda^*(G^{\mathrm{ab}})$, then $\chi(d)=\chi(\delta^{\mathrm{ab}})$. Hence, we get an injective homomorphism

(3.23)\begin{equation} \alpha: \frac{\Lambda^*(G^{\mathrm{ab}})}{\text{Im}(\omega_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})}\hookrightarrow \frac{\Omega^*_d(T_G)}{\text{Im}(\omega_{G}^{\delta})}. \end{equation}

Now if $\delta^{\mathrm{ab}}$ is not 2-divisible, then

\begin{align*}\frac{\Lambda^*(G^{\mathrm{ab}})}{\text{Im}(\omega_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})}\cong {\mathbb Z}/2{\mathbb Z}\cong \frac{\Omega^*_d(T_G)}{\text{Im}(\omega_{G}^{\delta})}.\end{align*}

If, instead, $\delta^{\mathrm{ab}}$ is 2-divisible, then condition (*) implies that

\begin{align*} \frac{\Lambda^*(G^{\mathrm{ab}})}{\text{Im}(\omega_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})}=0= \frac{\Omega^*_d(T_G)}{\text{Im}(\omega_{G}^{\delta})}. \end{align*}

In any case, the morphism α of Equation (3.23) is an isomorphism, which implies, by the snake lemma applied to Equation (3.22), that

\begin{align*} \frac{\text{Im}(\omega_{G}^{\delta})}{\text{Im}(\omega_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})}\xrightarrow{\cong} \frac{\Omega^*_d(T_G)}{\Lambda^*(G^{\mathrm{ab}})}. \end{align*}

Hence, we get the conclusion using again Equations (3.20) and (3.21).

A second case where Equation (3.15) is a push-out diagram is described in the following:

Theorem 3.16. Let G be a reductive group and fix $\delta\in\pi_1(G)$. If the family $C/S$ has genus $g(C/S) \gt 0$ and satisfies the following properties:

  1. (1) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ and $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$;

  2. (2) $\operatorname{RPic}^0(C/S)$ is torsion-free;

then the commutative diagram (3.15) is a push-out diagram.

This theorem was proved for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ with $g\geq 1$ (which satisfy the assumptions, by Remarks 2.3 and 2.5(1) and the Franchetta’s conjecture) in [Reference Fringuelli and Viviani21, Thm. C(2)].

Proof. The proof follows the same lines of the proof of [Reference Fringuelli and Viviani21, Thm. C(2)], as we now indicate.

First of all, because of the assumptions, the Picard group of $\operatorname{\mathrm{Bun}}_{T_G}^d(C/S)$ (where $d\in \pi_1(T_G)$ is a fixed lift of $\delta\in \pi_1(G)$) is generated by tautological classes by Theorem 3.9. Hence, using Theorem 3.8, we can define an action of the Weyl group $\mathscr W_G$ on $\operatorname{Pic}^d(\operatorname{\mathrm{Bun}}_{T_G}^d(C/S))$ by setting

\begin{align*} w\cdot d_{\widehat \pi}({\mathcal L}_{\chi}(M)):=d_{\widehat \pi}({\mathcal L}_{w\cdot \chi}(M)) \quad \text{for any }\chi\in \Lambda^*(T) \: \text{and any } M\in \operatorname{Pic}(C/S), \end{align*}

in such a way that the diagram (3.10) for $\operatorname{RPic}^d(\operatorname{\mathrm{Bun}}_{T_G}^d(C/S))$ is $\mathscr W_G$-equivariant.

Now, using the bottom exact sequence of Equation (3.10) and arguing as in the proof of [Reference Fringuelli and Viviani21, Lemma 5.3.3] for the case m = 2, we get that the subgroup of invariants of the above action of $\mathscr W_G$ sit in the following push-out diagram:

Therefore, it remains to show that the natural inclusion

(3.25)\begin{equation} \psi:\left(\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G} \hookrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \end{equation}

induced by the push-out diagram (3.24) and the commutative diagram (3.14) is an isomorphism. This will be achieved in two steps:

Step 1: $\operatorname{coker} \psi$ is torsion.

Indeed, consider the two inclusions

\begin{align*} \mathrm{ab}_{\sharp}^*: \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\stackrel{(\mathrm{ab}\circ \iota)_{\sharp}^*}{\hookrightarrow} \left(\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G}\stackrel{\psi}{\hookrightarrow} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S). \end{align*}

We get an induced exact sequence

\begin{align*} 0\to \frac{\left(\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G}}{\operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)}\to \frac{\operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)}{\operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)}\to \operatorname{coker} \psi\to 0. \end{align*}

By the push-out diagram (3.24) and using Lemmas 3.12 and 3.13, we get that

\begin{align*} \frac{\left(\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G}}{\operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)}\cong {\mathbb Z}^s, \end{align*}

where s is the number of quasi-simple factors of $G^{\mathrm{sc}}$. Moreover, arguing as in the proof of [Reference Fringuelli and Viviani21, Lemma 5.3.4], we deduce that

\begin{align*} \operatorname{rk} \frac{\operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)}{\operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)}\leq s. \end{align*}

By putting everything together, we deduce that $\operatorname{coker} \psi$ is a finite group.

Step 2: $\operatorname{coker} \psi$ is torsion-free.

Indeed, the natural inclusion of the subgroup of $\mathscr W_G$-invariants of $\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)$ factors is

\begin{align*} \left(\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G} \stackrel{\psi}{\hookrightarrow} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \stackrel{\iota_\sharp^*}{\hookrightarrow} \operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S), \end{align*}

where $\iota_{\sharp}^*$ is injective by Fact 3.2(2). Therefore, $\operatorname{coker} \psi$ injects into the quotient

\begin{align*} Q:=\frac{\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)}{\left(\operatorname{Pic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G}}=\frac{\operatorname{RPic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)}{\left(\operatorname{RPic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)\right)^{\mathscr W_G}} \end{align*}

Because of our three assumptions on the family $C/S$, Theorems 3.9 and 3.8 imply that $\operatorname{RPic} \operatorname{\mathrm{Bun}}_{T_G}^{d}(C/S)$ is torsion-free. Hence, the quotient Q is torsion-free by [Reference Fringuelli and Viviani21, Lemma 5.3.6], which implies that $\operatorname{coker} \psi$ is torsion-free.

We now explain how to obtain two alternative presentations of the relative Picard group of $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$, for a family of curves $C/S$ of positive genus and such that $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ and $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$, assuming that Equation (3.14) is a push-out diagram.

We first need the following:

Definition 3.17. (see [Reference Fringuelli and Viviani22, Cor. 2.6, Def. 3.9]) Let G be a reductive group with maximal torus TG and Weyl group $\mathscr W_G$, and fix $\delta\in \pi_1(G)$.

  1. (1) $ \operatorname{Bil}^{s,\mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}:=\left\{b\in \operatorname{Bil}^{s}(\Lambda(T_G))^{\mathscr W_G}\: : b_{|\Lambda(T_{\mathscr D(G)})\times \Lambda(T_{\mathscr D(G)})} \text{is even}\right\}. $

  2. (2) The Néron–Severi group of $\operatorname{\mathrm{Bun}}_G^{\delta}$ is the subgroup

    \begin{align*}\operatorname{NS}(\operatorname{\mathrm{Bun}}_G^{\delta})\subseteq \frac{\Lambda^*(T_G)}{\Lambda^*(T_{G^{\mathrm{ad}}})} \oplus \operatorname{Bil}^{s,\mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}\end{align*}

    consisting of all the elements $([\chi], b)$ such that

    (3.26)\begin{equation} \left[\chi_{|\Lambda(T_{\mathscr D(G)})}\right]=b(\delta\otimes -)_{|\Lambda(T_{\mathscr D(G)})}:=\left[b(d\otimes -)_{|\Lambda(T_{\mathscr D(G)})} \right] \in \frac{\Lambda^*(T_{\mathscr D(G)})}{\Lambda^*(T_{G^{\mathrm{ad}}})}, \end{equation}

    where $d\in \Lambda(T_G)$ is any lift of δ.

For a more detailed study of the Néron–Severi group $\operatorname{NS}(\operatorname{\mathrm{Bun}}_G^{\delta})$, see [Reference Fringuelli and Viviani22, Prop. 3.11].

Theorem 3.18. Assume that the family $C/S$ has genus $g(C/S) \gt 0$ and satisfies the following conditions:

  1. (1) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ and $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$;

  2. (2) either $\operatorname{RPic}^0(C/S)$ is torsion-free or $\mathscr D(G)$ is simply connected.

Then, there exists a commutative diagram, functorial in S and G,

where the rows are exact, the left vertical morphism is injective and the right vertical morphism is surjective.

Moreover, the image of $\omega_G^{\delta}\oplus \gamma_G^{\delta}$ is equal to

\begin{equation*} \text{Im}(\omega_G^{\delta}\oplus \gamma_G^{\delta})= \left\{([\chi], b)\in \operatorname{NS}(\operatorname{\mathrm{Bun}}_G^{\delta}) \: : \: \begin{aligned} & \left[\chi(x)-b(\delta\otimes x)\right]+(g-1)b(x\otimes x) \\ & \text{is divisible by } \delta(C/S), \text{for any } x\in \Lambda(T_G) \end{aligned} \right\}. \end{equation*}

This theorem was proved for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ for $g\geq 1$ (and an arbitrary reductive group) in [Reference Fringuelli and Viviani22, Thm. 1.1], and it can be deduced for a fixed curve C over $k=\overline k$ (in the case $g(C) \gt 0$, $\operatorname{End}(J_{C_{\overline\eta}})={\mathbb Z}$ and $\mathscr D(G)$ simply connected) from [Reference Biswas and Hoffmann7, Thm. 5.3.1].

Proof. Observe that our assumptions imply that Equation (3.14) is a push-out diagram (by Theorems 3.14 and 3.16), and that $\operatorname{Pic} \operatorname{\mathrm{Bun}}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)= \operatorname{Pic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)$ by Theorem 3.9.

Let us first describe the maps appearing in the above diagram (3.27):

$\bullet$ the map $\iota_G^{\delta}$ is defined by

\begin{align*} i_G^{\delta}(\chi\otimes M):=\langle {\mathcal L}_{\chi}, M \rangle_{\widehat \pi} \end{align*}

and $j_G^{\delta}$ is the restriction of $i_G^{\delta}$.

$\bullet$ the morphism $\omega_G^{\delta}$ is induced by the weight homomorphism

\begin{align*} \operatorname{wt}_G^{\delta}:\operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to \Lambda^*(\mathscr Z(G))=\frac{\Lambda^*(T_G)}{\Lambda^*(T_{G^{\mathrm{ad}}})} \end{align*}

coming from the exact sequence Equation (4.1).

$\bullet$ the morphism $\gamma_G^{\delta}$ is uniquely determined, using that the diagram (3.14) is a push-out, by

  1. (1) The composition $\gamma_G^{\delta}\circ \tau_G^{\delta}$ is the inclusion

    \begin{align*} \alpha: \left(\operatorname{Sym}^2\Lambda^*(T_G)\right)^{\mathscr W_G}\cong \operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G} \hookrightarrow \operatorname{Bil}^{s, \mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}. \end{align*}
  2. (2) The composition $\gamma_G^{\delta}\circ \mathrm{ab}_\#^*$ is equal to the following composition:

    \begin{align*} \operatorname{RPic}^{\operatorname{taut}} \operatorname{\mathrm{Bun}}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S) &\xrightarrow{\gamma_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}} (\Lambda^*(G^{\mathrm{ab}})\otimes \Lambda^*(G^{\mathrm{ab}}))^s \cong \operatorname{Bil}^{s}(\Lambda(G^{\mathrm{ab}}))\\ & \xrightarrow{B_{\mathrm{ab}}^*} \operatorname{Bil}^{s, \mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}, \end{align*}

    where $\gamma_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}$ is the homomorphism of Lemma 3.7 and $B_{\mathrm{ab}}^*$ is obtained by pull-back.

Now the proof is deduced from Theorems 3.83.9 and 3.14, arguing as in the proofs of [Reference Fringuelli and Viviani22, Thm. 3.6, Thm. 3.12].

We end this subsection by describing the relative Picard group of $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$, for a family of curves $C/S$ of genus zero and an arbitrary reductive group G. We first need the following:

Definition 3.19. (see [Reference Biswas and Hoffmann7, Def. 5.2.1]) Let G be a reductive group and let $\delta\in \pi_1(G)$. Define

\begin{align*} \operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1):=\left\{(\chi, b): l+b(d^{\mathrm{ss}},-)\in \Lambda^*(T_G)\right\}\subseteq \Lambda^*(\mathscr Z(G))\times \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}, \end{align*}

where $d^{\mathrm{ss}}$ is the image in $\Lambda(T_{G^{\mathrm{ss}}})$ of any lift $d\in \Lambda(T_G)$ of δ and $l+b(d^{\mathrm{ss}},-)$ is interpreted as an element of

\begin{align*}\Lambda^*(\mathscr Z(G))_{{\mathbb Q}}\oplus \Lambda^*(T_{G^{\mathrm{sc}}})_{{\mathbb Q}}=\Lambda^*(T_G)_{{\mathbb Q}}.\end{align*}

It is easily checked that the above definition does not depend on the choice of the lifting d of δ (see [Reference Biswas and Hoffmann7, Lemma 5.2.2]) and that it is functorial in G (see [Reference Biswas and Hoffmann7, Def. 5.2.7]).

Theorem 3.20. Let CS be a family of curves of genus g = 0 on a regular and integral quotient stack. Let G be a reductive group, fix $\delta\in \pi_1(G)$ and set $\delta^{\mathrm{ab}}:=\pi_1(\mathrm{ab})(\delta)\in \pi_1(G^{\mathrm{ab}})$. Fix a lift $d\in \Lambda(T_G)$ of δ and denote by $d^{\mathrm{ss}}$ its image in $\Lambda(T_{G^{\mathrm{ss}}})$.

There exists an injective homomorphism, functorial in S and G:

\begin{align*} c_G^{\delta}(C/S)=c_G^{\delta}: \operatorname{RPic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\to \operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1) \end{align*}

such that

  1. (1) if G = T is a torus, then $c_G^{\delta}$ coincides with the weight homomorphism;

  2. (2) the image of $c_G^{\delta}$ is equal to

    (3.28)\begin{align} \text{Im}(c_G^{\delta})= \begin{cases} \operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1) & \text{if } C/S \text{is Zariski locally trivial, } \\ \left\{(l,b)\in \operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1)\right. : & \text{if } C/S \text{is not Zariski locally trivial.} \\ \quad \left. l(\delta^{\mathrm{ab}})+b(d^{\mathrm{ss}}, d^{\mathrm{ss}}) \text{is even} \right\} & \end{cases}\nonumber\\ \end{align}

    In particular, if $C/S$ is not Zariski locally trivial, then $\text{Im}(c_G^{\delta})$ is an index two subgroup of $\operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1)$.

Note that the second subgroup in Equation (3.28) is well-defined since if $\widetilde d\in \Lambda(T_G)$ is another lift of δ, then its image $\widetilde d^{\mathrm{ss}}$ in $\Lambda(T_{G^{\mathrm{ss}}})$ is such that $\widetilde d^{\mathrm{ss}}=d^{\mathrm{ss}}+\epsilon$ for some $\epsilon \in \Lambda(T_{G^{\mathrm{sc}}})$, and we have

\begin{align*} b(\widetilde d^{\mathrm{ss}}, \widetilde d^{\mathrm{ss}})=b(d^{\mathrm{ss}},d^{\mathrm{ss}})+2b(d^{\mathrm{ss}},\epsilon)+b(\epsilon,\epsilon)\in b(d^{\mathrm{ss}},d^{\mathrm{ss}})+2{\mathbb Z}, \end{align*}

using that $b(\epsilon,\epsilon)\in 2{\mathbb Z}$ since b is an even symmetric bilinear form on $\Lambda(T_{G^{\mathrm{sc}}})$, and that $b(d^{\mathrm{ss}}, \epsilon)\in {\mathbb Z}$ by [Reference Biswas and Hoffmann7, Lemma 4.3.4].

Proof. Note that $C/S$ is Zariski locally trivial if and only if $C/S$ admits a section. Therefore, for a choice of a geometric generic point $\overline \eta$ of S, we get the following diagram:

with Cartesian squares, where

\begin{align*}n= \begin{cases} 1 & \text{if }C/S \text{is Zariski locally trivial,} \\ 0 & \text{if }C/S \text{is not Zariski locally trivial.} \end{cases} \end{align*}

The above diagram induces the following homomorphisms, functorial in S and in G:

(3.30)\begin{equation} \operatorname{RPic}\operatorname{\mathrm{Bun}}_{G,0,n}^{\delta} \hookrightarrow \operatorname{RPic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \hookrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1_{\overline \eta})\xrightarrow[\cong]{c_G^{\delta}({\mathbb P}^1_{\overline \eta})} \operatorname{NS}\operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1), \end{equation}

where the first two pullback homomorphisms are injective by Fact 3.2(1) (note that $\overline \eta$ is also a geometric generic point of ${\mathcal M}_{0,n}$) and the last isomorphism is the one of [Reference Biswas and Hoffmann7, Thm. 5.3.1(iii)]. Therefore, we get our desired injective homomorphism, functorial in S and G

\begin{align*} c_G^{\delta}(C/S): \operatorname{RPic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S) \hookrightarrow \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1_{\overline \eta})\xrightarrow[\cong]{c_G^{\delta}({\mathbb P}^1_{\overline \eta})} \operatorname{NS}\operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1), \end{align*}

which coincides with the weight homomorphism if G is a torus, because this is the case for the isomorphism $c_G^{\delta}({\mathbb P}^1_{\overline \eta})$ (see the proof of [Reference Biswas and Hoffmann7, Thm. 5.3.1(iii)]).

It remains to prove part (2) by distinguishing the two cases $C/S$ Zariski locally trivial or not.

If $C/S$ is Zariski locally trivial (and hence n = 1 in the above diagram), then we get that $c_G^{\delta}(C/S)$ is surjective since the composite homomorphism in Equation (3.30)

\begin{align*} c_G^{\delta}({\mathcal C}_{0,1}/{\mathcal M}_{0,1}): \operatorname{RPic}\operatorname{\mathrm{Bun}}_{G,0,1}^{\delta} \to \operatorname{NS}\operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1) \end{align*}

is surjective by [Reference Fringuelli and Viviani21, Thm. 5.0.2].

If $C/S$ is not Zariski locally trivial (and hence n = 0 in the above diagram), then we get that

\begin{equation*} \{(l,b)\in \operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1) : l(\delta^{\mathrm{ab}})+b(d^{\mathrm{ss}}, d^{\mathrm{ss}}) \text{is even}\}\subseteq \text{Im}(c_G^{\delta}(C/S)), \end{equation*}

since the same is true for the image of $c_G^{\delta}({\mathcal C}_0/{\mathcal M}_0)$ by [Reference Fringuelli and Viviani21, Thm. 5.0.2]. In order to prove the other inclusion, consider the following commutative diagram (for a chosen lift $d\in \Lambda(T_G)$ of δ):

where the bottom map is defined by (see [Reference Biswas and Hoffmann7, Def. 5.2.5])

\begin{align*} \begin{aligned} \iota_{\sharp}^{\operatorname{NS},*}: \operatorname{NS}\operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1) & \to \operatorname{NS}\operatorname{\mathrm{Bun}}_{T_G}^{d}({\mathbb P}^1)=\Lambda^*(T_G)\\ (l,b) &\mapsto l+b(d^{\mathrm{ss}},-). \end{aligned} \end{align*}

The above commutative diagram, together with Theorem 3.6(2), implies that

\begin{align*} \text{Im}(c_G^{\delta}(C/S))&\subseteq (\iota_{\sharp}^{\operatorname{NS},*})^{-1}(\text{Im}(c_{T_G}^d(C/S)))\\ &=\{(l,b)\in \operatorname{NS} \operatorname{\mathrm{Bun}}_G^{\delta}({\mathbb P}^1) : l(\delta^{\mathrm{ab}})+b(d^{\mathrm{ss}}, d^{\mathrm{ss}}) \text{is even}\}, \end{align*}

and we are done.

Corollary 3.21. Same assumptions of Theorem 3.20. There exists an exact sequence functorial in S and G

(3.31)\begin{equation} 0\to \operatorname{Pic} \operatorname{\mathrm{Bun}}_{G_{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\xrightarrow{\mathrm{ab}_\sharp^*} \operatorname{Pic} \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\xrightarrow{p_G^{\delta}} \left\{\begin{aligned} b\in \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}: \\ b^{{\mathbb Q}}(d^{\mathrm{ss}},-)_{|\Lambda(T_{\mathscr D(G)})}\text{is integral }\end{aligned} \right\}, \end{equation}

where the last homomorphism $p_G^{\delta}$ has image of index at most two and it is surjective if either $\mathscr D(G)$ is simply connected or $C/S$ is Zariski locally trivial.

Note that if $\mathscr D(G)$ is simply connected, then the last group of Equation (3.31) is equal to $ \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}$ by Lemma 3.13(3).

Proof. Theorem 3.20 implies that the following diagram

is Cartesian, where the map $\mathrm{ab}_{\sharp}^{\operatorname{NS},*}$ sends χ into $(\chi, 0)$. Therefore, we get that the cokernel of $\mathrm{ab}_{\sharp}^*$ injects into the cokernel of $\mathrm{ab}_{\sharp}^{\operatorname{NS},*}$, which is equal (by [Reference Biswas and Hoffmann7, Prop. 5.2.11]) to

\begin{align*} \operatorname{coker}(\mathrm{ab}_{\sharp}^{\operatorname{NS},*})=\left\{b\in \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}: b^{{\mathbb Q}}(d^{\mathrm{ss}},-)_{|\Lambda(T_{\mathscr D(G)})}\text{ is integral }\right\}. \end{align*}

This proves the existence of the exact sequence Equation (3.31), as well as of the following exact sequence:

\begin{align*} 0\to \operatorname{coker} \operatorname{wt}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}(C/S)\to \operatorname{coker} c_{G}^{\delta}(C/S)\to \operatorname{coker} p_G^{\delta} \to 0. \end{align*}

Since $\operatorname{coker} c_{G}^{\delta}(C/S)$ is a finite group of order at most two by Theorem 3.20 and it is trivial if $C/S$ is Zariski locally trivial, we deduce that the same is true for $\operatorname{coker} p_G^{\delta}$. Moreover, $\operatorname{coker} p_G^{\delta}$ is trivial if $\mathscr D(G)$ is simply connected by Theorem 3.14.

4. The rigidification of $ \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)$ by the centre

The aim of this section is to study, for a reductive group G, the $\mathscr Z(G)$-gerbe (see Equation (2.10))

\begin{equation*} \nu_G^{\delta}=\nu_G^{\delta}(C/S):\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\to \operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)\textit{[\!]} \mathscr Z(G):=\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S), \end{equation*}

obtained by rigidifying the stack $\operatorname{\mathrm{Bun}}_{G}^{\delta}(C/S)$ by the centre $\mathscr Z(G)$ of the reductive group G.

From the Leray spectral sequence

\begin{align*} E_{p,q}^2=H^p(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S), R^q(\nu_{G}^{\delta})_*(\operatorname{\mathbb{G}}_{m}))\Rightarrow H^{p+q}(\operatorname{\mathrm{Bun}}_G^{\delta}(C/S), \operatorname{\mathbb{G}}_{m}), \end{align*}

and using that $(\nu_G^{\delta})_*(\operatorname{\mathbb{G}}_{m})=\operatorname{\mathbb{G}}_{m}$ and that $R^1(\nu_{G}^{\delta})_*(\operatorname{\mathbb{G}}_{m})$ is the constant sheaf $\Lambda^*(\mathscr Z(G))=\operatorname{Hom}(\mathscr Z(G),\operatorname{\mathbb{G}}_{m})$, we get the exact sequence

(4.1)\begin{equation} \begin{aligned} & \operatorname{Pic}(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S))\stackrel{(\nu_G^{\delta})^*}{\hookrightarrow} \operatorname{Pic}(\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)) \xrightarrow{\operatorname{wt}_G^{\delta}} \Lambda^*(\mathscr Z(G)):=\operatorname{Hom}(\mathscr Z(G),\operatorname{\mathbb{G}}_{m}) \\ & \xrightarrow{\operatorname{obs}_G^{\delta}} H^2(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S), \operatorname{\mathbb{G}}_{m})\xrightarrow{(\nu_G^{\delta})^*} H^2(\operatorname{\mathrm{Bun}}_G^{\delta}(C/S), \operatorname{\mathbb{G}}_{m}), \end{aligned} \end{equation}

and an analogue one in which the Picard groups $\operatorname{Pic}$ are replaced by the relative Picard groups $\operatorname{RPic}$.

Recall (see [Reference Fringuelli and Viviani22, § 5]) the following geometric descriptions of the weight homomorphism $\operatorname{wt}_G^{\delta}$ and the obstruction homomorphism $\operatorname{obs}_G^{\delta}$:

  • given a line bundle ${\mathcal L}$ on $\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)$, the character $\operatorname{wt}_G^{\delta}({\mathcal L})\in \Lambda^*(\mathscr Z(G))$ is such that, for any ${\mathcal E}:=(E\to C_V)\in \operatorname{\mathrm{Bun}}_G^{\delta}(C/S)(V)$, we have the factorization

    \begin{align*} \operatorname{wt}_G^{\delta}(V):\mathscr Z(G)(V) \hookrightarrow \operatorname{Aut}_{\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)(V)}({\mathcal E})\xrightarrow{\operatorname{Aut}({\mathcal L}_{V})} \operatorname{Aut}_{{\mathcal O}_V}({\mathcal L}_V({\mathcal E}))=\operatorname{\mathbb{G}}_{m}(V), \end{align*}

    where the first homomorphism is given by the canonical action of $\mathscr Z(G)$ on every G-gerbe and the second homomorphism is induced by the functor of groupoids

    \begin{align*}{\mathcal L}_V:\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)(V)\to \{\text{Line bundles on } V\}\end{align*}

    determined by ${\mathcal L}$.

  • given any character $\lambda\in \operatorname{Hom}(\mathscr Z(G),\operatorname{\mathbb{G}}_{m})$, the element $\operatorname{obs}_G^{\delta}(\lambda)$ is the class in $H^2(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S), \operatorname{\mathbb{G}}_{m})$ of the $\operatorname{\mathbb{G}}_{m}$-gerbe $\lambda_*(\nu_G^{\delta})$ obtained by push-forwarding the $\mathscr Z(G)$-gerbe $\nu_G^{\delta}$ along λ.

Recall also (see [Reference Fringuelli and Viviani22, § 2.1]) that the character group of the centre $\mathscr Z(G)$ is equal to

\begin{align*}\Lambda^*(\mathscr Z(G))=\frac{\Lambda^*(T_G)}{\Lambda^*(T_{G^{\mathrm{ad}}})},\end{align*}

and it sits into the following exact sequence induced by the vertical exact sequence of Equation (2.5):

(4.2)\begin{align} 0\to \Lambda^*(G^{\mathrm{ab}})\xrightarrow{\overline{\Lambda_{\mathrm{ab}}^*}} \Lambda^*(\mathscr Z(G))=\frac{\Lambda^*(T_G)}{\Lambda^*(T_{G^{\mathrm{ad}}})} \xrightarrow{\overline{\Lambda_{\mathscr D}^*}} \Lambda^*(\mathscr Z(\mathscr D(G)))=\frac{\Lambda^*(T_{\mathscr D(G)})}{\Lambda^*(T_{G^{\mathrm{ad}}})} \to 0.\nonumber\\ \end{align}

Our goal is to determine the (relative) Picard group of the rigidification $\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S)$ and the group

(4.3)\begin{equation} \operatorname{coker}(\operatorname{wt}_G^{\delta}) \cong \text{Im}(\operatorname{obs}_G^{\delta})=\ker (\nu_G^{\delta})^*, \end{equation}

which is an obstruction to the triviality of the $\mathscr Z(G)$-gerbe $\nu_G^{\delta}$.

With this aim, we need to recall two crucial homomorphisms from [Reference Fringuelli and Viviani22].

Definition 4.1. (see [Reference Fringuelli and Viviani22, Definition/Lemma 2.8, Def. 5.3]) Let G be a reductive group with fixed maximal torus TG and Weyl group $\mathscr W_G$, and fix $\delta\in \pi_1(G)$.

  1. (1) There is a well-defined homomorphism (called evaluation homomorphism)

    (4.4)\begin{equation} \begin{aligned} \operatorname{ev}_{\mathscr D(G)}^{\delta}:\operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_{\mathscr D(G)})\vert \Lambda(T_{G^{\mathrm{ss}}}))^{\mathscr W_G} & \longrightarrow \frac{\Lambda^*(T_{\mathscr D(G)})}{\Lambda^*(T_{G^{\mathrm{ad}}})}, \\ b &\mapsto b(\delta^{\mathrm{ss}}\otimes -):=[b^{{\mathbb Q}}(d^{\mathrm{ss}}\otimes -)], \end{aligned} \end{equation}

    where $d^{\mathrm{ss}}\in \Lambda(T_{G^{\mathrm{ss}}})$ is any lift of $\delta^{\mathrm{ss}}:=\pi_1(\mathrm{ss})(\delta)\in \pi_1(G^{\mathrm{ss}})=\frac{\Lambda(T_{G^{\mathrm{ss}}})}{\Lambda(T_{G^{\mathrm{sc}}})}$ and $d^{{\mathbb Q}}$ is the rational extension of b to $\Lambda(T_{G^{\mathrm{ss}}})$.

  2. (2) The Néron–Severi group of $\operatorname{\mathfrak{Bun}}_G^{\delta}$ is the subgroup

    \begin{align*}\operatorname{NS}(\operatorname{\mathfrak{Bun}}_{G}^{\delta})\subset \operatorname{Bil}^{s,\mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}\end{align*}

    consisting of those $b\in \operatorname{Bil}^{s,\mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}$ such that

    (4.5)\begin{equation} 0=b(\delta\otimes -)_{|\Lambda(T_{\mathscr D(G)})}:=\left[b(d\otimes -)_{|\Lambda(T_{\mathscr D(G)})} \right] \in \frac{\Lambda^*(T_{\mathscr D(G)})}{\Lambda^*(T_{G^{\mathrm{ad}}})}, \end{equation}

    where $d\in \Lambda(T_G)$ is any lift of δ.

Note that there is an injective homomorphism

\begin{align*} \begin{aligned} \nu^{\delta, \operatorname{NS}}: \operatorname{NS}(\operatorname{\mathfrak{Bun}}_{G}^{\delta}) & \hookrightarrow \operatorname{NS}(\operatorname{\mathrm{Bun}}_G^{\delta})\\ b & \mapsto ([0],b). \end{aligned} \end{align*}

For a more detailed description of $\operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta})$, see [Reference Fringuelli and Viviani22, Prop. 5.4].

Example 1. If $\mathscr D(G)$ is simply connected, i.e. $\mathscr D(G)=G^{\mathrm{sc}}$, then the cokernel of $\operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}$ can be computed explicitly as it follows:

  1. (1) If $G^{\mathrm{sc}}=G_1^{\mathrm{sc}}\times \cdots \times G_r^{\mathrm{sc}}$ is the decomposition of $G^{\mathrm{sc}}$ into simply connected and almost simple algebraic groups and $\delta=(\delta_1,\ldots, \delta_r)\in \pi_1(G^{\mathrm{ad}})=\pi_1(G_1^{\mathrm{ad}})\times \cdots \times \pi_1(G_r^{\mathrm{ad}})$, then

    \begin{align*} \operatorname{coker} \operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}\cong \operatorname{coker} \operatorname{ev}_{G_1^{\mathrm{sc}}}^{\delta_1}\times \cdots \times \operatorname{coker} \operatorname{ev}_{G_r^{\mathrm{sc}}}^{\delta_r}. \end{align*}
  2. (2) If $G^{\mathrm{sc}}$ is simply connected and almost simple, then the cokernel of $\operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}$ is equal to (see [Reference Fringuelli and Viviani22, § 7]):

    1. (a) If $G^{\mathrm{sc}}=\operatorname{SL}_n$ (and hence $G^{\mathrm{ad}}=\operatorname{PSL}_n$), then, for any $\delta\in \pi_1(\operatorname{PSL}_n)={\mathbb Z}/n{\mathbb Z}$, we have that

      \begin{align*} \operatorname{coker} \operatorname{ev}_{\operatorname{SL}_n}^{\delta}=\frac{{\mathbb Z}}{\gcd(n,\delta){\mathbb Z}}. \end{align*}
    2. (b) If $G^{\mathrm{sc}}=\operatorname{Spin}_{2n+1}$ (and hence $G^{\mathrm{ad}}=\operatorname{SO}_{2n+1}$), then, for any $\delta\in \pi_1(\operatorname{SO}_{2n+1})={\mathbb Z}/2{\mathbb Z}$, we have that

      \begin{align*} \operatorname{coker} \operatorname{ev}_{\operatorname{Spin}_{2n+1}}^{\delta}={\mathbb Z}/2{\mathbb Z}. \end{align*}
    3. (c) If $G^{\mathrm{sc}}=\operatorname{Sp}_{2n}$ (and hence $G^{\mathrm{ad}}=\operatorname{PSp}_{2n}$), then, for any $\delta\in \pi_1(\operatorname{PSp}_{2n})={\mathbb Z}/2{\mathbb Z}$, we have that

      \begin{align*} \operatorname{coker} \operatorname{ev}_{\operatorname{Sp}_{2n}}^{\delta}= \begin{cases} {\mathbb Z}/2{\mathbb Z} & \text{if either }\delta= 0 \text{or } n \text{is even}, \\ 0 & \text{otherwise.} \end{cases} \end{align*}
    4. (d) If $G^{\mathrm{sc}}=\operatorname{Spin}_{2n}$ (and hence $G^{\mathrm{ad}}=\operatorname{PSO}_{2n}$), then, for any

      \begin{align*}\delta\in \pi_1(\operatorname{PSO}_{2n})= \begin{cases} {\mathbb Z}/4{\mathbb Z} & \text{if } n \: \text{is odd,}\\ {\mathbb Z}/2{\mathbb Z}\times {\mathbb Z}/2{\mathbb Z} & \text{if }n \: \text{is even,} \end{cases} \end{align*}

      we have that

      \begin{align*} \operatorname{coker} \operatorname{ev}_{\operatorname{Spin}_{2n}}^{\delta}= \begin{cases} {\mathbb Z}/4{\mathbb Z} & \text{if } \delta=0 \text{ and }n \: \text{is odd,}\\ {\mathbb Z}/2{\mathbb Z}\times {\mathbb Z}/2{\mathbb Z} & \text{if } \delta=0 \:\text{and } n \text{ is even,} \\ {\mathbb Z}/2{\mathbb Z} & \text{if } \operatorname{ord}(\delta)=2,\\ 0 & \text{if } \operatorname{ord}(\delta)=4. \end{cases} \end{align*}
    5. (e) If $G^{\mathrm{sc}}={\mathbb E}_{6}^{\mathrm{sc}}$, then, for any $\delta\in \pi_1({\mathbb E}_6^{\mathrm{ad}})={\mathbb Z}/3{\mathbb Z}$, we have that

      \begin{align*} \operatorname{coker} \operatorname{ev}_{{\mathbb E}_6^{\mathrm{sc}}}^{\delta}= \begin{cases} {\mathbb Z}/3{\mathbb Z} & \text{if } \delta=0, \\ 0 & \text{if } \delta\neq 0. \end{cases} \end{align*}
    6. (f) If $G^{\mathrm{sc}}={\mathbb E}_{7}^{\mathrm{sc}}$, then, for any $\delta\in \pi_1({\mathbb E}_7^{\mathrm{ad}})={\mathbb Z}/2{\mathbb Z}$, we have that

      \begin{align*} \operatorname{coker} \operatorname{ev}_{{\mathbb E}_7^{\mathrm{sc}}}^{\delta}= \begin{cases} {\mathbb Z}/2{\mathbb Z} & \text{if } \delta= 0, \\ 0 & \text{if } \delta\neq 0. \end{cases} \end{align*}
    7. (g) If $G^{\mathrm{sc}}$ is of type ${\mathbb E}_8$ or ${\mathbb F}_4$ or ${\mathbb G}_2$, then

      \begin{align*} \operatorname{coker} \operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}=0. \end{align*}

We first describe the (relative) Picard group of the rigidification $\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S)$ for families of positive genus, under certain assumptions.

Theorem 4.2. Let CS be a family of curves of genus g > 0 on a regular and integral quotient stack with geometric generic fibre $C_{\overline \eta}$. Assume that the following two conditions hold true:

  1. (1) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ and $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$;

  2. (2) either $\operatorname{RPic}^0(C/S)$ is torsion-free or $\mathscr D(G)$ is simply connected.

Then, for any fixed $\delta\in \pi_1(G)$, we have the following exact sequence, functorial in S and G:

(4.6)\begin{equation} 0 \to \Lambda^*(G^{\mathrm{ab}})\otimes \operatorname{RPic}^0(C/S) \xrightarrow{\overline{j_G^{\delta}}} \operatorname{RPic}(\operatorname{\mathfrak{Bun}}_G^{\delta}(C/S))\xrightarrow{\overline{\gamma_G^{\delta}}} \operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta}), \end{equation}

where $\overline{j_G^{\delta}}$ and $\overline{\gamma_G^{\delta}}$ are uniquely determined by

\begin{align*} (\nu_G^{\delta})^*\circ \overline{j_G^{\delta}}=j_G^{\delta}\quad \text{and } \quad \nu_G^{\delta,\operatorname{NS}} \circ \overline{\gamma_G^{\delta}}= (\omega_G^{\delta}\oplus \gamma_G^{\delta})\circ (\nu_G^{\delta})^*, \end{align*}

see Theorem 3.18.

Moreover, the image of $\overline{\gamma_G^{\delta}}$ is equal to

(4.7)\begin{equation} \text{Im}(\overline{\gamma_G^{\delta}})= \left\{b\in \operatorname{NS}(\operatorname{\mathfrak{Bun}}_G^{\delta})\: : \: \begin{aligned} & b(\delta\otimes x)+(g-1)b(x\otimes x) \text{is a multiple of } \delta(C/S) \\ & \text{for any } x\in \Lambda(T_G) \end{aligned} \right\}. \end{equation}

This theorem was proved for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ for $g\geq 1$ in [Reference Fringuelli and Viviani22, Thm. 5.5].

Proof. This is deduced from Theorem 3.18, arguing as in the proofs of [Reference Fringuelli and Viviani22, Thm. 5.5].

We now describe the cokernel of the weight homomorphism.

Theorem 4.3. Let CS be a family of curves of genus g > 0 on a regular and integral quotient stack with geometric generic fibre $C_{\overline \eta}$. Assume that the following two conditions hold true:

  1. (1) $\operatorname{End}(J_{C_{\overline \eta}}) ={\mathbb Z}$ and $\operatorname{RPic}(C/S)=\operatorname{Pic}_{C/S}(S)$;

  2. (2) either $\operatorname{RPic}^0(C/S)$ is torsion-free or $\mathscr D(G)$ is simply connected.

Then, for any fixed $\delta\in \pi_1(G)$, we have the following exact sequence, There exists an exact sequence

(4.8)\begin{equation} 0\to \operatorname{coker}(\overline{\gamma_G^{\delta}})\xrightarrow{\partial_G^{\delta}} \operatorname{Hom}\left(\Lambda(G^{\mathrm{ab}}), \frac{{\mathbb Z}}{\delta(C/S){\mathbb Z}}\right)\xrightarrow{\widetilde{\Lambda_{\mathrm{ab}}^*}} \operatorname{coker}(\operatorname{wt}_G^{\delta})\xrightarrow{\widetilde{\Lambda_{\mathscr D}^*}} \operatorname{coker}(\operatorname{ev}_{\mathscr D(G)}^{\delta})\to 0, \end{equation}

where $\widetilde{\Lambda_{\mathrm{ab}}^*}$ and $\widetilde{\Lambda_{\mathscr D}^*}$ are the homomorphisms induced by, respectively, $\overline{\Lambda_{\mathrm{ab}}^*}$ and $\overline{\Lambda_{\mathscr D}^*}$ of Equation (4.2) and $\partial_G^{\delta}$ is defined as follows:

(4.9)\begin{equation} \begin{aligned} \partial_G^{\delta}: \operatorname{coker}(\overline{\gamma_G^{\delta}}) & \longrightarrow \operatorname{Hom}\left(\Lambda(G^{\mathrm{ab}}), \frac{{\mathbb Z}}{\delta(C/S){\mathbb Z}}\right)\\ [b] & \mapsto \left\{x\mapsto \left[b(\delta\otimes \widetilde x)+(1-g) b(\widetilde x\otimes \widetilde x)\right]\right\}, \end{aligned} \end{equation}

where $b\in \operatorname{NS}(\mathfrak{Bun}_{G,g,n}^{\delta})\subset \operatorname{Bil}^{s,\mathscr D-\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}$ and $\widetilde x\in \Lambda(T_G)$ is any lift of $x\in \Lambda(G^{\mathrm{ab}})$.

This theorem was proved for the universal family ${\mathcal C}_{g,n}\to {\mathcal M}_{g,n}$ for $g\geq 1$ in [Reference Fringuelli and Viviani22, Thm. 5.7] and for a curve C over $k=\overline k$ of genus $g(C)\geq 3$ in [Reference Biswas and Hoffmann8, Thm. 6.8] (and in both results the general case of an arbitrary reductive group is also treated).

Proof. This is deduced from Theorem 3.18, arguing as in the proofs of [Reference Fringuelli and Viviani22, Thm. 5.7].

Corollary 4.4. Same assumptions as in Theorem 4.3.

  1. (1) If $\delta(C/S)=1$, then there is an isomorphism

    \begin{align*}\widetilde{\Lambda_{\mathscr D}^*}: \operatorname{coker}(\operatorname{wt}_G^{\delta})\xrightarrow{\cong} \operatorname{coker}(\operatorname{ev}_{\mathscr D(G)}^{\delta}).\end{align*}
  2. (2) If G = T is a torus and $d\in \Lambda(T)$, then there is an exact sequence

    (4.10)\begin{equation} 0\to \operatorname{coker}(\overline{\gamma_T^{d}})\xrightarrow{\partial_T^{d}} \operatorname{Hom}\left(\Lambda(T), \frac{{\mathbb Z}}{\delta(C/S){\mathbb Z}}\right) \to \operatorname{coker}(\operatorname{wt}_T^{d})\to 0, \end{equation}

Moreover, we have that

\begin{align*} \begin{aligned} & \operatorname{coker}(\overline{\gamma_T^d})\cong \frac{{\mathbb Z}}{\frac{\delta(C/S)}{\gcd(\delta(C/S),\mathrm{div}(d)+1-g)}{\mathbb Z}}\oplus \left[ \frac{{\mathbb Z}}{\frac{\delta(C/S)}{\gcd(\delta(C/S),g-1,\mathrm{div}(d))}{\mathbb Z}}\right]^{\oplus(\dim(T)-1)} \\ &\operatorname{coker}(\omega_T^d)\cong \frac{{\mathbb Z}}{\gcd(\delta(C/S),\mathrm{div}(d)+1-g){\mathbb Z}}\oplus \left[\frac{{\mathbb Z}}{\gcd(\delta(C/S),g-1,\mathrm{div}(d)){\mathbb Z}}\right]^{\oplus(\dim(T)-1)}, \\ \end{aligned} \end{align*}

where $\mathrm{div}(d)$ is the divisibility of d in the lattice $\Lambda(T)$, with the convention that $\operatorname{coker}(\overline{\gamma_T^d})=\{0\}$ if $\delta(C/S)=0$ (when the above expression for $\operatorname{coker}(\overline{\gamma_T^d})$ is not well-defined).

The above Corollary for $G=\operatorname{\mathbb{G}}_{m}$ recovers the main result of [Reference Mestrano and Ramanan35]: a Poincaré line bundle exists on $\operatorname{\mathfrak{Bun}}_{\operatorname{\mathbb{G}}_{m}}^d(C/S)\times_S C$ (which is equivalent to the triviality of the $\operatorname{\mathbb{G}}_{m}$-gerbe $\nu_{\operatorname{\mathbb{G}}_{m}}^d$) if and only if $\gcd(\delta(C/S),d+1-g)=1$, where $d\in \Lambda(\operatorname{\mathbb{G}}_{m})={\mathbb Z}$.

Proof. Part (1) and the first part of (2) follow from Theorem 4.2.

The second part of (2) follows by choosing a basis $\{e_1,\ldots, e_r\}$ of $\Lambda(T)$ (with $r=\dim T$) such that $d=\mathrm{div}(d)e_1$ and computing the composition

\begin{align*} \overline{\partial_T^d}: \operatorname{Bil}^s(\Lambda(T))\twoheadrightarrow \operatorname{coker}(\overline{\gamma_T^d}) \xrightarrow{\partial_T^d} \operatorname{Hom}\left(\Lambda(T), \frac{{\mathbb Z}}{\delta(C/S){\mathbb Z}}\right) \end{align*}

on the basis $\left\{\{e_i^*\otimes e_i^*\}_i, \{e_i^*\otimes e_j^*+e_j^*\otimes e_i^*\}_{i \gt j}\right\}$ of $\operatorname{Bil}^s(\Lambda(T))$:

\begin{align*} \begin{cases} \overline{\partial_T^d}(e_1^*\otimes e_1^*)=[\mathrm{div}(d)+1-g]e_1^*, \\ \overline{\partial_T^d}(e_i^*\otimes e_i^*)=[1-g]e_i^*\: \text{for any } i\geq 2,\\ \overline{\partial_T^d}(e_1^*\otimes e_i^*+e_i^*\otimes e_1^*)=\mathrm{div}(d) e_i^*\: \text{for any } i\geq 2,\\ \overline{\partial_T^d}(e_i^*\otimes e_j^*+e_j^*\otimes e_i^*)=0 \: \text{for any } 2\leq i \lt j.\\ \end{cases} \end{align*}

We end this subsection by computing the relative Picard group of $\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S)$ and the group $\operatorname{coker}(\operatorname{wt}_G^{\delta})$ for families of genus zero, under certain assumptions.

Theorem 4.5. Let $\pi:C\to S$ is a family of smooth curves of genus $g(C/S)=0$ over an integral and regular quotient stack S. Assume that at least one of the following two assumptions is satisfied:

  1. (1) the family $C/S$ is Zariski locally trivial;

  2. (2) the derived subgroup $\mathscr D(G)$ is simply connected.

For a given $\delta\in \pi_1(G)$, consider the homomorphism

(4.11)\begin{equation} \begin{aligned} \widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta}: \left\{\begin{aligned} b\in \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}: \\ b^{{\mathbb Q}}(d^{\mathrm{ss}},-)_{|\Lambda(T_{\mathscr D(G)})}\text{is integral }\end{aligned} \right\} & \longrightarrow \frac{\Lambda^*(T_{\mathscr D(G)})}{\Lambda^*(T_{G^{\mathrm{ad}})}} \\ b &\mapsto b(\delta^{\mathrm{ss}}\otimes -):=[b^{{\mathbb Q}}(d^{\mathrm{ss}}\otimes -)], \end{aligned} \end{equation}

where $d^{\mathrm{ss}}\in \Lambda(T_{G^{\mathrm{ss}}})$ is any lift of $\delta^{\mathrm{ss}}:=\pi_1(\mathrm{ss})(\delta)\in \pi_1(G^{\mathrm{ss}})=\frac{\Lambda(T_{G^{\mathrm{ss}}})}{\Lambda(T_{G^{\mathrm{sc}}})}$ and $d^{{\mathbb Q}}$ is the rational extension of b to $\Lambda(T_{G^{\mathrm{ss}}})$.

  1. (1) We have an isomorphism

    \begin{align*} \operatorname{RPic}(\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S))\cong \ker(\widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta}), \end{align*}

    which is functorial in S and G.

  2. (2) The homomorphism $\overline{\Lambda_{\mathscr D}^*}$ of Equation (4.2) induces a surjection

    (4.12)\begin{equation} \widetilde{\Lambda_{\mathscr D}^*}:\operatorname{coker}(\operatorname{wt}_G^{\delta})\twoheadrightarrow \operatorname{coker}(\widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta}), \end{equation}

    whose kernel is equal to

    (4.13)\begin{equation} \ker( \widetilde{\Lambda_{\mathscr D}^*})= \begin{cases} 0 & \text{if either } \delta(C/S)=1 \: \text{or } \delta^{\mathrm{ab}} \: \text{is 2-divisible in } \Lambda^*(G^{\mathrm{ab}}),\\ {\mathbb Z}/2{\mathbb Z} & \text{if } \delta(C/S)=2 \: \text{and } \delta^{\mathrm{ab}} \: \text{is not 2-divisible in } \Lambda^*(G^{\mathrm{ab}}).\\ \end{cases} \end{equation}

This theorem can be deduced for the universal family ${\mathcal C}_{0,n}\to {\mathcal M}_{0,n}$ with $n\geq 1$ (which is Zariski locally trivial) from [Reference Fringuelli and Viviani22, Rmk. 5.10]. Note that if $\mathscr D(G)$ is simply connected, then the homomorphism $\widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta}$ coincides with the homomorphism $\operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}$ by Lemma 3.13(3).

Proof. Set

\begin{align*} Q:= \left\{\begin{aligned} b\in \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}: \\ b^{{\mathbb Q}}(d^{\mathrm{ss}},-)_{|\Lambda(T_{\mathscr D(G)})}\text{is integral }\end{aligned} \right\}. \end{align*}

Consider the following diagram:

where the first row is exact by Corollary 3.21, the second row is exact by Equation (4.2) and the diagram is commutative by the same proof of [Reference Fringuelli and Viviani22, Prop. 5.2, Prop. 5.4].

By applying the snake lemma and using that $\operatorname{wt}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}$ is injective by Theorem 3.6(2), we get an exact sequence

\begin{align*} 0&\to\operatorname{RPic}(\operatorname{\mathfrak{Bun}}_{G}^{\delta}(C/S))\to \ker(\widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta} \xrightarrow{\partial} \operatorname{coker}(\operatorname{wt}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}) \to \operatorname{coker}(\operatorname{wt}_G^{\delta})\xrightarrow{\widetilde{\Lambda_{\mathscr D}^*}} \operatorname{coker}(\widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta})\\ &\to 0. \end{align*}

Observe now that Theorem 3.6(3) implies that $\operatorname{coker}(\operatorname{wt}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})$ is equal to the group in the right-hand side of Equation (4.13). Hence, we conclude by the previous exact sequence and the following:

Claim: the coboundary map $\partial$ is zero.

Indeed, assume that $\operatorname{coker}(\operatorname{wt}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}})\cong {\mathbb Z}/2{\mathbb Z}$; otherwise, the statement is trivially true. In particular, $C/S$ is not Zariski locally trivial, and hence $\mathscr D(G)=G^{\mathrm{sc}}$ due to our assumptions. This implies that $\widehat{\operatorname{ev}}_{\mathscr D(G)}^{\delta}=\operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}$ as observed above. Let $b\in \ker(\operatorname{ev}_{G^{\mathrm{sc}}}^{\delta})\subset \left(\operatorname{Sym}^2 \Lambda^*(T_{G^{\mathrm{sc}}})\right)^{\mathscr W_G}$. By Lemma 3.13(1), we can choose $\widetilde b\in \left(\operatorname{Sym}^2 \Lambda^*(T_{G})\right)^{\mathscr W_G}$ such that $\widetilde b_{|\Lambda(T_{G^{\mathrm{sc}}})\times \Lambda(T_{G^{\mathrm{sc}}})}=b$, which implies that the class of $\tau_G^{\delta}(\widetilde b)\in \operatorname{RPic} \left(\operatorname{\mathrm{Bun}}_G^{\delta}(C/S)\right)$ is a lift of b. By the same argument of [Reference Fringuelli and Viviani22, Def./Lemma 3.7, Prop. 5.2], we have that

\begin{align*} \operatorname{wt}_G^{\delta}(\tau_G^{\delta}(\widetilde b))=\widetilde b(\delta\otimes -):=[\widetilde b(d\otimes -)]\in \frac{\Lambda^*(T_G)}{\Lambda^*(T_{G^{\mathrm{ad}}})}, \end{align*}

where $d\in \Lambda(T_G)$ is any lift of δ. Since b is in the kernel of $\operatorname{ev}_{G^{\mathrm{sc}}}^{\delta}$, the element $\operatorname{wt}_G^{\delta}(\tau_G^{\delta}(\widetilde b))$ lies in the image of $\overline{\Lambda_{\mathrm{ab}}^*}$, i.e. there exists $\chi\in \Lambda^*(G^{\mathrm{ab}})$ such that

(4.15)\begin{equation} \widetilde b(\delta\otimes -)=\chi(\Lambda_{\mathrm{ab}}(-)). \end{equation}

By the definition of the boundary homomorphism, we have that

\begin{align*} \partial(b)=[\chi(\delta^{\mathrm{ab}})] \in {\mathbb Z}/2{\mathbb Z}\cong \operatorname{coker}(\operatorname{wt}_{G^{\mathrm{ab}}}^{\delta^{\mathrm{ab}}}). \end{align*}

Since $\delta^{\mathrm{ab}}=\Lambda_{\mathrm{ab}}(d)$ for any lift $d\in \Lambda(T_G)$ of δ, Equation (4.15) implies that

\begin{align*}\chi(\delta^{\mathrm{ab}})=\widetilde b(\delta\otimes b)=\widetilde b(d\otimes d).\end{align*}

But $\widetilde b(d\otimes d)$ is even since $\widetilde b \in \left(\operatorname{Sym}^2 \Lambda^*(T_{G})\right)^{\mathscr W_G}\cong \operatorname{Bil}^{s,\operatorname{ev}}(\Lambda(T_G))^{\mathscr W_G}$, which forces $\partial(b)$ to be zero, q.e.d.

Acknowledgement

We thank Guido Lido for useful conversations concerning Remark 2.5.

Funding Statement

F.V. is funded by the MIUR ‘Excellence Department Project’ MATH@TOV, awarded tothe Department of Mathematics, University of Rome Tor Vergata, CUP E83C18000100006, by the PRIN 2022 ‘Moduli Spaces and Birational Geometry’ and the PRIN-2020 ‘Curves, Ricci flat Varieties and their Interactions’ funded by MIUR (Ministero dell’Istruzione e del Merito), by the project EXPL/MAT-PUR/1162/2021 (DOI:10.54499/EXPL/MAT-PUR/1162/2021) funded by FCT (Fundação para a Ciência e a Tecnologia), bythe CMUC (Centro de Matemática da Universidade de Coimbra).

Footnotes

1 the proof of loc. cit. for the universal family ${\mathcal C}_{g,n}/{\mathcal M}_{g,n}$ extends mutatis mutandis to an arbitrary family $C/S$.

2 the proof of loc. cit. for the universal family ${\mathcal C}_{g,n}/{\mathcal M}_{g,n}$ extends mutatis mutandis to an arbitrary family $C/S$.

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