2. Definitions and notation

In the following section, we recall the theory of (compactified) Jacobians following the treatment of [Reference Pagani and Tommasi21]. Readers familiar with this subject are encouraged to skip to the next section and refer back to this section as needed.

Associated to a complex, nonsingular projective curve C is a Jacobian $J^0(C)$ which is a complex, projective abelian variety whose dimension is equal to the genus of the curve. These are moduli spaces parametrising degree 0 line bundles on C up to isomorphism. The group law on $J^0(C)$ is by tensor product. In fact, as an abstract group, it is isomorphic to $(\mathbb{R}/\mathbb{Z})^{2g}$ and is the subgroup of $\mathrm{Pic}(C)$ consisting of degree 0 line bundles. For $g \geq 1$ , it has n-torsion isomorphic to $(\mathbb{Z}/n\mathbb{Z})^{2g}$ . In particular, for every n, there is an element of order n in $J^0(C)$ that generates a subgroup of order n. If $d \in \mathbb{Z}$ , there is a variety $J^d(C)$ parametrising degree d line bundles which is isomorphic to $J^0(C)$ as a variety where the isomorphism is given by tensoring with a fixed line bundle of degree d. $J^d(C)$ is no longer an algebraic group but $J^0(C)$ acts freely on $J^d(C)$ via tensor products.

Similarly, singular complex projective curves C have associated generalised Jacobian varieties $J^{\underline{0}}(C)$ which in general fail to be proper over $\mathbb{C}$ (see below for the definition). These Jacobian varieties are abelian group schemes and there are several approaches to compactifying these varieties.

Given a nodal curve C and its total normalisation $v\;:\; C^v \rightarrow C$ , if $C_1,...,C_t$ are the irreducible components of $C^v$ , then the multidegree of $\mathcal{L} \in \mathrm{Pic}(C)$ is the vector $\underline{\mathrm{deg}(\mathcal{L})} = (\mathrm{deg}_{C_i}(v^*\mathcal{L}|_{C_i}))_i$ . Its total degree, $\mathrm{deg}(\mathcal{L})$ is given by the sum of the components of the vector $\underline{\mathrm{deg}(\mathcal{L})}$ . As a group, $J^{\underline{0}}(C)$ is the subgroup of Pic(C) consisting of line bundles of multidegree $\underline{0}$ and for each $\underline{d}\in \mathbb{Z}^t$ , there is a scheme $J^{\underline{d}}(C)$ parametrising line bundles of multidegree $\underline{d}$ on C. In particular, these are all isomorphic to $J^{\underline{0}}(C)$ where the isomorphism is given by tensoring with a fixed line bundle of multidegree $\underline{d}$ .

Given a nodal curve C with dual graph $\Gamma(C)$ , we define:

\begin{align*}b_1(\Gamma(C)) = |E(\Gamma(C))| - |V(\Gamma(C))| + 1.\end{align*}

If $\delta$ is the number of nodes of C, then this quantity is $\delta - t + 1$ .

There is an exact sequence of group schemes: ([Reference Arbarello, Cornalba and Griffiths2, p.89])

\begin{align*}1 \rightarrow (\mathbb{C}^{\times})^{b_1(\Gamma(C))} \rightarrow J^{\underline{0}}(C) \xrightarrow{\mathcal{L}\mapsto v^*(\mathcal{L})} J^{\underline{0}}(C^v) \cong \prod_{i=1}^tJ^0(C_i) \rightarrow 0.\end{align*}

When all the $C_i$ are genus 0 curves, $J^{\underline{d}}(C) \cong (\mathbb{C}^{\times})^{b_1(\Gamma(C))}$ .

The construction of Jacobians also works for families of smooth curves and for each g, n such that $2g -2 + n\gt0$ , there exists a universal Jacobian $\mathcal{J}^d_{g,n}$ which is a DM stack along with a smooth, proper morphism $\mathcal{J}^d_{g,n} \rightarrow \mathcal{M}_{g,n}$ such that the fiber over any geometric point $[(C;\;p_1,...,p_n)]$ of $\mathcal{M}_{g,n}$ is the Jacobian variety $J^d(C)$ .

A coherent sheaf on a nodal curve C has rank 1 if the stalk at each generic point of C has length 1. It is torsion free if it has no embedded components and it is singular at P if it fails to be locally free at P. If $\mathcal{F}$ is a torsion free sheaf on C, we say it is simple if its automorphism group is $\mathbb{C}^{\times}$ . This is equivalent to the condition that removing the singular points of $\mathcal{F}$ from C does not disconnect C.

Every rank 1, torsion free, simple sheaf $\mathcal{F}$ on a nodal curve C can be associated with a pair $(S(\mathcal{F}), \underline{\mathrm{deg}(\mathcal{F})})$ . Here $S(\mathcal{F})$ is the set of nodes of C at which $\mathcal{F}$ fails to be locally free. Since $\mathcal{F}$ is simple, $S(\mathcal{F})$ is a non-disconnecting subset of nodes of C. The multidegree $\underline{\mathrm{deg}(\mathcal{F})}$ is the multidegree of the maximal torsion free quotient of the pullback of $\mathcal{F}$ under the total normalisation of C. In other words, the partial normalisation $C_S$ of C at the nodes $S(\mathcal{F})$ of C is connected.

If C is a nodal curve, a degree d fine compactified Jacobian $\overline{J}^d(C)$ is a nonempty, connected, proper, open subscheme of $Simp^d(C)$ where $Simp^d(C)$ is the scheme parametrising rank 1, torsion free, simple coherent sheaves on C. It is smoothable if there exists a regular smoothing $\mathcal{C}\rightarrow Spec(\mathbb{C}[[t]])$ of C such that the fiber over $0 \in \mathbb{C}[[t]]$ of a morphism $U \rightarrow Spec(\mathbb{C}[[t]])$ where U is an open, proper subscheme of $Simp^d(\mathcal{C}/\mathbb{C}[[t]])$ is $\overline{J}^d(C)$ .

A degree d fine compactified universal Jacobian is an open substack of $Simp^d(\overline{C}_{g,n}/\overline{\mathcal{M}}_{g,n})$ (see [Reference Pagani and Tommasi21] for a definition) that is proper over $\overline{\mathcal{M}}_{g,n}$ . In particular, since $Simp^d(\overline{C}_{g,n}/\overline{\mathcal{M}}_{g,n})$ is representable over $\overline{\mathcal{M}}_{g,n}$ and since open immersions of DM stacks are representable, any fine compactified universal Jacobian is representable over $\overline{\mathcal{M}}_{g,n}$ .

We now define stability conditions and explain their relation to fine, smoothable compactified Jacobians. If $G \subset \Gamma$ is a connected, spanning subgraph of $\Gamma$ , define

\begin{align*}S^d_{\Gamma}(G) = \left \{ \underline{d}\in \mathbb{Z}^{|V(\Gamma)|}\;:\; \sum_{v \in V(\Gamma)}d(v) = d - |E(\Gamma)\setminus E(G)|\right \} \subset \mathbb{Z}^{|V(\Gamma)|}.\end{align*}

If $\mathcal{F}$ is a rank 1, torsion free, simple sheaf on a nodal curve C, then $\underline{\mathrm{deg}}(\mathcal{F}) \in S^d_{\Gamma}(\Gamma(\mathcal{F}))$ where $\Gamma(\mathcal{F})$ is the graph obtained from $\Gamma(C)$ by removing the edges corresponding to the nodes of C at which $\mathcal{F}$ fails to be locally free.

The twister of a graph $\Gamma$ at the vertex v is defined to be the element of $\mathbb{Z}^{|V(\Gamma)|}$ defined by:

\begin{align*} \mathrm{Tw}_{\Gamma,v}(w) = \left\{\begin{array}{l@{\quad}l} \# \text{ edges of }\Gamma\text{ having endpoints } v\text{ and } w, &\quad v \neq w,\\[4pt]\qquad -\# \text{ non-loop edges of }\Gamma & \\[-5pt]& \;\;v = w. \\[-5pt]\text{ having one of its endpoints }v = w, & \end{array}\right. .\end{align*}

The twister group, $\mathrm{Tw}(\Gamma)$ is the subgroup of $\mathbb{Z}^{|V(\Gamma)|}$ generated by the elements $\lbrace\mathrm{Tw}_{\Gamma,v}\rbrace_{v \in V(\Gamma)}$ . We have the inclusions $\mathrm{Tw}(\Gamma) \subset S^0_{\Gamma}(\Gamma) \subset \mathbb{Z}^{|V(\Gamma)|}$ and therefore, for a connected, spanning subgraph $G \subset \Gamma$ , $\mathrm{Tw}(G)$ acts on $S^d_{\Gamma}(G)$ by vector addition.

A degree d stability condition $\sigma$ on $\Gamma$ is a set of pairs $(G, \underline{d})$ such that $\underline{d} \in S^d_{\Gamma}(G)$ where $G \subset \Gamma$ is a connected, spanning subgraph. The pairs $(G, \underline{d})$ are additionally required to satisfy the following two conditions:

(1) if G is a connected, spanning subgraph of $\Gamma$ , then for all edges e of $E(\Gamma)\setminus E(G)$ with endpoints $v_1$ and $v_2$ , if $(G,\underline{d}) \in \sigma$ , then $(G \cup \lbrace e \rbrace, \underline{d} + \underline{e}_{v_i})$ is in $\sigma$ for $i = 1,2$ where $\underline{e}_{v_i}$ is the standard basis vector of $\mathbb{Z}^{|V(\Gamma)|}$ corresponding to vertex $v_i$ ;

(2) for every connected, spanning subgraph G of $\Gamma$ :

\begin{align*} \sigma(G) = \lbrace \underline{d}\;:\; (G, \underline{d}) \in \sigma \rbrace \subset S^d_{G}(G)\end{align*}

is a minimal, complete set of representatives for the action of the twister group Tw(G) on $S^d_{\Gamma}(G)$ .

For every connected, spanning subgraph G of $\Gamma$ , we have $|\sigma(G)| = c(G)$ by [Reference Pagani and Tommasi21, remark 4·4].

For a nodal curve C, the scheme $Simp^d(C)$ has a stratification into locally closed subsets $Simp^d(C) = \underset{(G, \underline{d})}{\bigsqcup} \overline{J}_{(G,\underline{d})}(C)$ where $\overline{J}_{(G,\underline{d})}(C)$ is the locus whose points correspond to sheaves $\mathcal{F}$ where $\Gamma(\mathcal{F}) = G$ and $\underline{\mathrm{deg}(\mathcal{F})} = \underline{d}$ . Here the disjoint union is over all connected, spanning subgraphs G of $\Gamma$ and all $\underline{d}\in \mathbb{Z}^{|V(\Gamma)|}$ such that

\begin{align*}\sum_{i = 1}^{|V(\Gamma)|}d_i = d - |E(\Gamma)\setminus E(G)|.\end{align*}

We view these as schemes, endowed with the reduced schematic structure.

Given a stability condition $\sigma$ on the dual graph $\Gamma$ of a nodal curve C, a rank 1, torsion free simple sheaf $\mathcal{F}$ is $\sigma$ -stable if $(\Gamma(\mathcal{F}), \underline{\mathrm{deg}(\mathcal{F}}))$ is in $\sigma$ where $\Gamma(\mathcal{F})$ is the subgraph of $\Gamma(C)$ obtained by removing edges of $\Gamma(C)$ corresponding to nodes of C at which $\mathcal{F}$ fails to be locally free.

This will play an important role in our calculation of the orbifold Euler characteristics of fine compactified universal Jacobians. To be precise, for every fine, smoothable compactified Jacobian $\overline{J}^d(C)$ of C, there is some unique stability condition $\sigma$ on $\Gamma(C)$ such that $\overline{J}^d(C) = \overline{J}_{\sigma}^d(C)$ .

A non-degenerate polarisation $\phi$ (see [Reference Pagani and Tommasi21]) on a stable graph $\Gamma$ defines a stability condition $\sigma_{\phi}$ on $\Gamma$ . We also have the notion of a non-degenerate universal polarisation, which is a collection $\phi = (\phi_{\Gamma})_{\Gamma \in G(g,n)}$ such that each $\phi_{\Gamma}$ is a non-degenerate polarisation on $\Gamma$ and such that the $\phi_{\Gamma}$ are compatible with graph morphisms. Every non-degenerate polarisation on a graph $\Gamma$ gives rise to a smoothable, fine compactified Jacobian on curves with dual graph $\Gamma$ . Additionally, non-degenerate universal polarisations give rise to fine compactified universal Jacobians.

The fine compactified universal Jacobians $\overline{\mathcal{J}}^d_{g,n}(\phi)$ over $\overline{\mathcal{M}}_{g,n}$ corresponding to a universal polarisation $\phi = (\phi_{\Gamma})_{\Gamma \in G(g,n)}$ are introduced in [Reference Kass and Pagani17].

There are fine compactified universal Jacobians that do not arise from universal polarisations. For example, in [Reference Pagani and Tommasi20, section 6], fine compactified universal Jacobians $\overline{\mathcal{J}}^d_{g,n}$ , not arising from a universal stability condition are found for $n \geq 6$ . In fact, it is rarely the case that all fine compactified Jacobians arise from universal stability conditions.

3. Orbifold Euler characteristics of separated, finite type, complex DM stacks

In this section, we recall basic properties of the orbifold Euler characteristics of finite type, separated Deligne–Mumford (DM) stacks defined over $\mathbb{C}$ and prove Proposition 3·9 which is central in our calculation.

The existence of an orbifold Euler characteristic satisfying these properties is well known within the mathematical community. Once existence of such a definition has been shown, uniqueness follows from its properties.

Let $\mathcal{V}_0 = \mathcal{M}\setminus\mathcal{U}_0$ . If $\mathcal{V}_{0} \neq \emptyset$ , repeat the above process to find a nonempty open substack $\mathcal{U}_1$ of $\mathcal{V}_0$ with the property that $\mathcal{U}_1$ has a finite, surjective, étale cover by a scheme. Set $\mathcal{V}_1 = \mathcal{V}_0\setminus\mathcal{U}_0$ . Continue inductively until $\mathcal{V}_i = \emptyset$ . This process must terminate after finitely many iterations since we obtain a chain of closed subsets $\mathcal{V}_0 \supsetneq \mathcal{V}_1 \supsetneq ...$ of $\mathcal{M}$ . Therefore, using the fact that $\mathcal{M}$ is noetherian, there must be some finite n such that $\mathcal{V}_n = \emptyset$ . We obtain $\mathcal{M} = \bigsqcup_{i=0}^n\mathcal{U}_i$ where the $\mathcal{U}_i$ are locally closed, integral substacks of $\mathcal{M}$ , each having a finite, surjective étale morphism from a scheme.

Remark 3·6. An explicit construction of orbifold Euler characteristics for finite type, separated DM stacks over $\mathbb{C}$ can be defined as follows. Take a locally closed stratification of $\mathcal{M} = \bigsqcup_{i = 1}^n\mathcal{U}_i$ as in Lemma 3·4 where there is a finite, surjective, étale morphism $U_i \xrightarrow{f_i} \mathcal{U}_i$ from some scheme $U_i$ to $\mathcal{U}_i$ for each i. We can define

\begin{align*} \chi_{orb}(\mathcal{M}) = \sum_{i = 1}^n\frac{\chi_{top}(U_i^{an})}{\mathrm{deg}(f_i)}. \end{align*}

This can be shown to be independent of the choice of stratification and of the $f_i$ once such a stratification has been chosen. The properties in Theorem 3·1 can easily be seen to follow from this definition.

Proposition 3·9. Suppose $\mathcal{M} \rightarrow \mathcal{N}$ is a proper, surjective, representable morphism of separated, finite type DM stacks such that the topological Euler characteristic of the fiber of any geometric point of $\mathcal{N}$ is independent of the choice of geometric point. Then

\begin{align*}\chi_{orb}(\mathcal{M}) = \chi_{top}(F^{an})\chi_{orb}(\mathcal{N}),\end{align*}

where F is the fiber over any geometric point of $\mathcal{N}$ .

We obtain the following cartesian diagram

We take a locally closed stratification $U = \bigsqcup_{j=1}^n U_j$ as in Theorem 3·8. Taking connected components, we may further assume that they are connected. Letting $F_{j}$ be a fiber of $\mathcal{M}|_{U_j} \rightarrow U_j$ by Theorem 3·8, we obtain

\begin{align*} \chi_{top}((\mathcal{M}\times_{\mathcal{N}}U|_{U_j})^{an}) = \chi_{top}(F_{j}^{an})\chi_{top}(U_j^{an}).\end{align*}

Using the fact that $F_{j}$ is a fiber of $\mathcal{M} \rightarrow \mathcal{N}$ and writing F for any general fiber of this morphism,

\begin{align*} \chi_{top}(F^{an}) = \chi_{top}(F_{j}^{an}).\end{align*}

By Lemma 3·4, we can obtain a locally closed stratification of $\mathcal{M}$ into finitely many locally closed, integral substacks. Using the fact that over each integral substack $\mathcal{M}' \subset \mathcal{M}$ , $g|_{\mathcal{M}'}$ is a finite, surjective étale morphism of degree $\mathrm{deg}(f)$ , by properties (1) and (3) of Theorem 3·1,

\begin{align*}\chi_{orb}(\mathcal{M}) = \frac{\chi_{orb}(\mathcal{M}\times_{\mathcal{N}}U)}{\mathrm{deg}(f)} = \frac{\chi_{top}((\mathcal{M}\times_{\mathcal{N}}U)^{an})}{\mathrm{deg}(f)}.\end{align*}

We compute

\begin{align*} \chi_{orb}(\mathcal{M}) & = \frac{\chi_{top}((\mathcal{M}\times_{\mathcal{N}}U)^{an})}{\mathrm{deg}(f)}\\ & =\frac{1}{\mathrm{deg}(f)}\sum_{j=1}^n\chi_{top}((\mathcal{M}\times_{\mathcal{N}}U|_{U_j})^{an})\\ & = \frac{1}{\mathrm{deg}(f)}\sum_{j=1}^n\chi_{top}(U_j^{an})\chi_{top}(F^{an}) \\ & = \chi_{top}(F^{an})\frac{\chi_{top}(U^{an})}{\mathrm{deg}(f)} = \chi_{top}(F^{an})\chi_{orb}(\mathcal{N}).\end{align*}

4. Proof of the main result

If $\overline{\mathcal{J}}^d_{g,n}$ is a fine compactified universal Jacobian over $\overline{\mathcal{M}}_{g,n}$ , then the fiber $\overline{J}^d(C)$ over any point $[(C;\;p_1,...,p_n)]$ of $\overline{\mathcal{M}}_{g,n}$ is a degree d, fine smoothable compactified Jacobian of C. The smoothability of the fibers $\overline{J}^d(C)$ follows from the fact that the morphism $\overline{\mathcal{J}}^d_{g,n}\rightarrow \overline{\mathcal{M}}_{g,n}$ is smooth over the open, dense substack $\mathcal{M}_{g,n}$ of $\overline{\mathcal{M}}_{g,n}$ . Therefore, every fiber $\overline{J}^d(C)$ over a point $[(C;\;p_1,...,p_n)]$ is of the form $\overline{J}^d(C) = \overline{J}^d_{\sigma}(C)$ for some stability condition $\sigma$ on $\Gamma(C)$ .

Let $C_S$ be the partial normalisation of C at the subset of nodes corresponding to edge set S in $E(\Gamma(C))$ . For any line bundle $\mathcal{L}$ on $C_S$ , by [Reference Melo and Viviani19, proposition 1·14 (iii)], if $S_v$ is the set of self-edges in S incident at vertex v and $C^v$ is the corresponding irreducible component of C

(4·1) \begin{align}\mathrm{deg}_{C^v}(\mathcal{L}|_{C^v_S}) = \mathrm{deg}_{C^v}((v_S)_*\mathcal{L}|_{C^v}) - |S_v|.\end{align}

As in [Reference Melo and Viviani19], for a nodal curve C, given a fine, smoothable compactified Jacobian $\overline{J}^d_{\sigma}(C)$ corresponding to a stability condition $\sigma$ , we have the stratification $\overline{J}^d_{\sigma}(C) = \bigsqcup_{(G, \underline{d}) \in \sigma}\overline{J}_{(G,\underline{d})}(C)$ where $\overline{J}_{(G,\underline{d})}(C)$ is the locus whose points correspond to sheaves $\mathcal{F}$ where $\Gamma(\mathcal{F}) = G$ and $\underline{\mathrm{deg}(\mathcal{F})} = \underline{d}$ . These are locally closed subsets which we view as schemes endowed with the reduced schematic structure.

Lemma 4·2. If $\sigma$ is a stability condition on a graph $\Gamma$ and S is a set of edges whose removal does not result in a disconnected graph, and if $\Gamma_S$ is the resulting connected graph, then we can define a stability condition $\sigma_S$ on $\Gamma_S$ to be:

\begin{align*}\sigma_S = \left\{\begin{array}{lr} (G, (d_v - |S_v|)_{v \in V(\Gamma)})\;:\; G \subset \Gamma_S \text{ is spanning and connected},\\ \;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;(d_v)_{v \in V(\Gamma)} \in \sigma(G) \end{array}\right\}. \end{align*}

Moreover, if $\sigma$ is a stability condition on $\Gamma$ of degree d, then $\sigma_S$ is a degree

\begin{align*}d_S = d + (|S| - \underset{v\in V(\Gamma)}{\sum}|S_v|),\end{align*}

or alternatively,

\begin{align*}d_S = d + \#\lbrace\text{edges in }S \text{ that are not self-edges}\rbrace.\end{align*}

Proof. We have:

\begin{align*} \sigma_S \subset \lbrace\text{connected, spanning subgraphs of }\Gamma_S\rbrace\times\mathbb{Z}^{|V(\Gamma_S)|}.\end{align*}

So it suffices to check that the two conditions in the definition of a degree $d_S$ stability condition hold.

1. (1) If G is a connected, spanning subgraph of $\Gamma_S$ , then if e is an edge in $E(\Gamma_S) \setminus E(G)$ , then for $(d_v)_v \in \sigma_S(G)$ , we have $(d_v + |S_v|)_v \in \sigma(G)$ and therefore if $v_1$ and $v_2$ are the endpoints of e, $\underline{e}_{v_i} + (d_v + |S_v|)_v $ is in $\sigma(G \cup \lbrace e \rbrace)$ and $\underline{e}_{v_i} + (d_v )_v $ is in $\sigma_S(G\cup \lbrace e \rbrace)$ for $i = 1,2$ .

2. (2) For each connected, spanning subgraph G of $\Gamma_S$ and for $\underline{d} \in \sigma_S(G)$ , we have:

   \begin{align*} \underset{v \in V(\Gamma)}{\sum}d_v = d - \underset{v \in V(\Gamma)}{\sum}|S_v| - |E(\Gamma)\setminus E(G)| \\= d + (|S| - \underset{v \in V(\Gamma)}{\sum}|S_v|) - |E(\Gamma_S)\setminus E(G)|\\ = d_S - |E(\Gamma_S)\setminus E(G)|.\end{align*}
   Therefore $\sigma_S(G) \subset S^{d_S}_{\Gamma_S}(G)$ . We also have $S^{d_S}_{\Gamma_S}(G) = S^{d}_{\Gamma}(G) - (|S_v|)_v$ and therefore, since $\sigma(G)$ is a minimal, complete set of representatives for the action of Tw(G) on $S^{d_S}_{\Gamma_S}(G)$ , using the fact that $\sigma_S(G) = \sigma(G) - (|S_v|)_v$ .

Given a stability condition $\sigma$ on $\Gamma = \Gamma(C)$ , we write:

\begin{align*} \overline{J}_{\sigma,\Gamma_S}(C) = \bigsqcup_{\underline{d} \in \sigma(\Gamma_S)}\overline{J}_{(\Gamma_S,\underline{d})}(C) \subset \overline{J}^d_{\sigma}(C).\end{align*}

The following proof is adapted from the proof of [Reference Melo and Viviani19, theorem 4·1].

Theorem 4·3. Given a nodal curve and a degree d stability condition, $\sigma$ on $\Gamma = \Gamma(C)$ , there is a morphism $(v_S)_*\;:\; Simp^{d_S}(C_S) \rightarrow Simp^{d}(C)$ induced by the normalisation $v_S\;:\; C_S \rightarrow C$ . It gives rise to an isomorphism

\begin{align*} (\overline{J}^{d_S}_{\sigma_{S}}(C_S))_{sm} = \overline{J}^{d_S}_{\sigma_S,\Gamma_S}(C_S) \cong \overline{J}^d_{\sigma, \Gamma}(C).\end{align*}

Here $(\overline{J}^{d_S}_{\sigma_{S}}(C_S))_{sm}$ denotes the smooth locus of $\overline{J}^{d_S}_{\sigma_{S}}(C_S)$ , or alternatively, the locus where points correspond to line bundles.

Proof. The morphism $(v_S)_*\;:\; Simp^{d_S}(C_S) \rightarrow Simp^{d}(C)$ is a monomorphism as a result of [Reference Esteves, Gagne and Kleiman11, lemma 2·4], which may be applied with families of reduced, not just integral curves (see proof of [Reference Melo and Viviani19, theorem 4·1]). It states that for a given scheme T, the functor

\begin{align*} \left\{\begin{array}{lr}T\text{-flat rank 1, torsion free}\\ \text{sheaves on } C_S\times T \text{ which}\\ \text{have degree }d\text{ over fibers}\\\text{of } C_S\times T \rightarrow T\end{array}\right\} \xrightarrow{(v_{S,T})_*} \left\{\begin{array}{lr}T\text{-flat rank 1, torsion free}\\ \text{sheaves on } C\times T \text{ which}\\ \text{have degree }d\text{ over fibers}\\\text{of } C\times T \rightarrow T\end{array}\right\},\end{align*}

where $v_{S,T}$ is the morphism $v_{S,T}:C_S\times T \rightarrow C \times T$ , is a fully faithful embedding. By Equation (4·1) and Lemma 4·2, this induces a morphism:

\begin{align*}(v_S)_*\;:\; \overline{J}^d_{\sigma_S}(C_S) \rightarrow \bigsqcup_{G \subset \Gamma_S}\overline{J}_{\sigma,G}(C)\subset \overline{J}^d_{\sigma}(C)\end{align*}

over $\bigsqcup_{G \subset \Gamma_S}\overline{J}_{\sigma,G}(C)$ . This is a morphism from a proper scheme to a separated scheme and is therefore a proper monomorphism so is a closed immersion. By Lemma 4·1 and Equation (4·1), it induces a bijection of geometric points on the restriction $(\overline{J}^{d_S}_{\sigma_{S}}(C_S))_{sm}\rightarrow \overline{J}^d_{\sigma, \Gamma_S}(C)$ over $\overline{J}^d_{\sigma, \Gamma_S}(C)$ . Therefore, the morphism $(\overline{J}^{d_S}_{\sigma_{S}}(C_S))_{sm} \rightarrow \overline{J}^d_{\sigma, \Gamma_S}(C)$ is an isomorphism.

Corollary 1. Suppose we have a fine, smoothable compactified Jacobian $\overline{J}^d_{\sigma}(C)$ of a nodal curve C corresponding to a stability condition $\sigma$ on $\Gamma = \Gamma(C)$ and a subset $S \subset E(\Gamma(C))$ whose removal results in a connected graph. Then $\overline{J}_{\sigma,\Gamma_S}(C)$ has a stratification into $|\sigma_S(\Gamma_S)| = c(\Gamma_S)$ strata, each of which is isomorphic to a generalised Jacobian on $C_S$ . By abuse of notation, we write

\begin{align*}\overline{J}_{\sigma,\Gamma_S}(C) = \underset{\underline{d} \in \sigma_S(\Gamma_S)}{\bigsqcup}J^{\underline{d}}(C_S),\end{align*}

and

\begin{align*}\overline{J}^d_{\sigma}(C) = \underset{\substack{S \subset E(\Gamma)\\ \text{non-disconnecting}}}{\bigsqcup}\underset{\underline{d} \in \sigma_S(\Gamma_S)}{\bigsqcup}J^{\underline{d}}(C_S),\end{align*}

where $J^{\underline{d}}(C_S)$ is the generalised Jacobian of $C_S$ of multidegree $\underline{d}$ .

Let $G(g,n)^0\subset G(g,n)$ be the set of representatives of isomorphism classes of stable graphs where all vertices have genus 0. We recall the notation that if C is a nodal curve:

\begin{align*}b_1(\Gamma(C)) = |E(\Gamma(C))| - |V(\Gamma(C))| + 1 \geq 0.\end{align*}

This follows from [Reference Bejleri5, proposition 2·2]

Proof. This follows from the fact that for finite type separated schemes, the topological Euler characteristic is additive with respect to locally closed stratifications, the stratification given in Theorem 4·3 and Lemma 4·5. For each non-disconnecting subset $S \subset E(C)$ , the partial normalisation $C_{S}$ has dual graph with vertices having the same genera as those of $\Gamma = \Gamma(C)$ . So for each $\underline{d} \in \sigma_{S}$ , by Lemma 4·5, $\chi_{top}((J^{\underline{d}}(C_S))^{an}) = 0$ and therefore:

\begin{align*}\chi_{top}((\overline{J}^d_{\sigma}(C))^{an}) = \sum\limits_{\substack{S \subset E(\Gamma)\\ \text{non-disconnecting}}}\chi_{top}((\overline{J}_{\sigma, \Gamma_S}(C))^{an})\\ = \sum\limits_{\substack{S \subset E(\Gamma)\\ \text{ non-disconnecting}}}\sum_{\underline{d} \in \sigma_{S}}\chi_{top}((J^{\underline{d}}(C_{S}))^{an}) = 0. \end{align*}

Lemma 4·6. Let C be a nodal curve such that $\Gamma(C) \in G(g,n)^0$ , let $\underline{d} \in \mathbb{Z}^{|V(\Gamma(C))|}$ be any multidegree and $S \subset E(\Gamma(C))$ , then:

\begin{align*} \chi_{top}((J^{\underline{d}}(C_{S}))^{an}) = \begin{cases}1\;\;\;\;\; \Gamma(C_S)\text{ is a tree},\\ 0\;\;\;\;\text{ otherwise.}\end{cases}\end{align*}

Corollary 3. If $[(C,p_1,...,p_n)]$ is a nodal curve of genus 0 such that the corresponding stable graph $\Gamma = \Gamma(C)$ lies in $G(g,n)^0$ , then:

\begin{align*} \chi_{top}((\overline{J}^d_{\sigma}(C))^{an}) = c(\Gamma)\end{align*}

for any stability condition $\sigma$ on $\Gamma$ .

Proof. By the additivity of the orbifold Euler characteristic with respect to locally closed stratifications:

\begin{align*}\chi_{top}(\overline{J}^d_{\sigma}(C)) = \sum_{S \subset E(\Gamma)}\chi_{top}(\overline{J}_{\sigma, \Gamma_S}(C))\\ = \sum_{S \subset E(\Gamma)}\sum_{\underline{d} \in \sigma_S(\Gamma_S)}\chi_{orb}(J^{\underline{d}}(C_{S}))\\ = \sum_{\lbrace S \subset E(\Gamma)\;:\; \Gamma_S \text{ is a tree}\rbrace}|\sigma_S(\Gamma_S)|.\end{align*}

The first equality follows from the stratification $\overline{J}^d_{\sigma}(C) = \underset{S \subset E(\Gamma)}{\bigsqcup}\overline{J}_{\sigma,\Gamma_S}(C)$ . The second follows from the stratification given in Corollary 1 and the third follows from Lemma 4·5.

Since $|\sigma_S(\Gamma_S)| = c(\Gamma_S) = 1$ , whenever $\Gamma_S$ is a tree, it follows that $\chi_{top}(\overline{J}^d_{\sigma}(C)) = c(\Gamma)$ .

Theorem 4·7. For all $d \in \mathbb{Z}$ , $g,n \geq 0$ such that $2g-2+n \gt 0$ and all fine compactified universal Jacobians $\overline{\mathcal{J}}^d_{g,n}$ of degree d,

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \sum_{\Gamma \in G(g,n)^0}c(\Gamma)\chi_{orb}(\mathcal{M}^{\Gamma}).\end{align*}

In particular, this is independent of d and the choice of fine compactified universal Jacobian.

Proof. The stratification of $\overline{\mathcal{M}}_{g,n}$ by dual graph induces a stratification of $\overline{\mathcal{J}}^d_{g,n} = \underset{\Gamma \in G(g,n)}{\bigsqcup}\overline{\mathcal{J}}^d_{g,n}|_{\mathcal{M}^{\Gamma}}$ . By additivity of orbifold Euler characteristics with respect to locally closed stratifications:

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \sum_{\Gamma \in G(g,n)}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}|_{\mathcal{M}^{\Gamma}}).\end{align*}

Suppose $\Gamma \in G(g,n)$ and $[(C^{\Gamma};\;p_1,...,p_n)]$ is in $\mathcal{M}^{\Gamma}(\mathbb{C})$ such that

$\overline{J}^d_{\sigma(C^{\Gamma})}(C^{\Gamma})$ is the fiber over $[(C^{\Gamma};\;p_1,...,p_n)]$ which is a smoothable, fine compactified Jacobian with $\sigma(C^{\Gamma})$ being a corresponding stability condition. Then combining Proposition 3·9 with Corollary 2 and Corollary 3, we obtain:

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}|_{\mathcal{M}^{\Gamma}}) = \chi_{orb}(\mathcal{M}^{\Gamma})\chi_{top}(\overline{J}^d_{\sigma(C^{\Gamma})}(C^{\Gamma})) \\= \begin{cases}c(\Gamma)\chi_{orb}(\mathcal{M}^{\Gamma})\;\;\; \text{if }\Gamma \in G(g,n)^0\\0\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\; \text{otherwise}.\end{cases}\end{align*}

So $\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \underset{\Gamma \in G(g,n)^0}{\sum}c(\Gamma)\chi_{orb}(\mathcal{M}^{\Gamma})$ .

Theorem 4·8. For all g and n such that $2g-2+n \gt 0$ ,

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \frac{1}{2^g(g!)}\chi(\overline{\mathcal{M}}_{0,2g+n}),\end{align*}

where $\chi(\overline{\mathcal{M}}_{0,2g+n})$ is the ordinary topological Euler characteristic of the variety $\overline{\mathcal{M}}_{0,2g+n}$ .

Proof. Let $\widehat{G}(g,n)^0$ be a set of representatives of isomorphism classes of pairs $(\Gamma, T)$ such that $[\Gamma] \in G(g,n)^0$ and T is a spanning tree of $\Gamma$ . An isomorphism of $(\Gamma,T)$ is an automorphism of $\Gamma$ fixing T and we denote this group by $\mathrm{Aut}(\Gamma,T)$ . The group $\mathrm{Aut}(\Gamma)$ acts on the set of spanning trees of $\Gamma$ . The stabiliser of a fixed spanning tree T under this action is given by $\mathrm{Aut}(\Gamma,T)$ . Therefore,

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \sum_{\Gamma \in G(g,n)^0}c(\Gamma)\chi_{orb} (\mathcal{M}^{\Gamma})\\=\sum_{\Gamma \in G(g,n)^0}\sum\limits_{\substack{T \text{ is a}\\\text{spanning}\\ \text{tree of }\Gamma}}\chi_{orb}(\mathcal{M}^{\Gamma}) \\ = \sum_{(\Gamma, T) \in \widehat{G}(g,n)^0}|\mathrm{orb}(T)|\chi_{orb}(\mathcal{M}^{\Gamma}).\end{align*}

Additionally, by [Reference Bini and Harer7]:

\begin{align*}\chi_{orb}(\mathcal{M}^{\Gamma}) = \frac{\prod_{v \in V(\Gamma)}\chi_{orb}(\mathcal{M}_{0,n(v)})}{|\mathrm{Aut}(\Gamma)|}.\end{align*}

We combine this with the fact that by the orbit stabiliser theorem, $|\mathrm{Aut}(\Gamma)| = |\mathrm{Aut}(\Gamma, T)||\mathrm{orb}(T)|$ (where T is any spanning tree of $\Gamma$ ) to obtain:

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \sum_{(\Gamma, T) \in \widehat{G}(g,n)^0}|\mathrm{orb}(T)|\frac{\prod_{v \in V(\Gamma)}\chi_{orb}(\mathcal{M}_{0,n(v)})}{|\mathrm{Aut}(\Gamma)|} \\= \sum_{(\Gamma, T) \in \widehat{G}(g,n)^0}\frac{\prod_{v \in V(\Gamma)}\chi_{orb}(\mathcal{M}_{0,n(v)})}{|\mathrm{Aut}(\Gamma, T)|}.\end{align*}

We define a surjective function $\phi\;:\; G(0, 2g+n) \rightarrow \widehat{G}(g,n)^0$ . Gluing pairs of markings $n+2i-1, n+2i$ for $1 \leq i \leq g$ of $T' \in G(g,n)^0$ forms a stable graph $\Gamma$ with n legs of genus g and the images of the original edges in T ^′ result in a spanning tree T or $\Gamma$ . We define $\phi(T') = (\Gamma, T)$ . We have $|\phi^{-1}([(\Gamma,T)])| = {2^g(g!)}/{|\mathrm{Aut}(\Gamma,T)|}$ which can be seen as follows.

Fixing $(\Gamma,T)$ in $\hat{G}(g,n)^0$ , any T ^′ in the preimage can be obtained by matching pairs of half-edges which form an edge in $E(\Gamma)\setminus E(T)$ to the entries of the g pairs $(n+1,n+2),...,(2g+n-1,2g+n)$ . Then T ^′ is obtained by cutting these edges and identifying the corresponding half-edges with the markings following the assignments previously described. There are $g!$ ways to match pairs of half-edges in $E(\Gamma)\setminus E(T)$ with pairs $(n+1,n+2),...,(2g+n-1, 2g+n)$ . Once the pairs of half-edges have been assigned, there are $2^g$ ways of determining the ordering of the half-edges within the pairs. Let S be the set of these $2^g(g!)$ choices. Then there is a surjective map $S \rightarrow \phi^{-1}(\Gamma,T)$ where the image can be identified with the orbit classes of an action of $\mathrm{Aut}(\Gamma,T)$ on S. This action is described as follows. If $T' \in S$ and there is an element $\sigma$ of $\mathrm{Aut}(\Gamma,T)$ permuting the half-edges in the edge (1, 2), then $\sigma \cdot T'$ is the element of S obtained by swapping markings 1 and 2 of T ^′. This action is free so all the orbits, which partition S have size $|\mathrm{Aut}(\Gamma, T)|$ and therefore:

\begin{align*}|\phi^{-1}((\Gamma,T))| =\frac{|S|}{|\mathrm{Aut}(\Gamma,T)|} = \frac{2^g(g!)}{|\mathrm{Aut}(\Gamma,T)|}.\end{align*}

Observing that $G(0,2g+n)^0 = G(0,2g+n)$ , we obtain:

\begin{align*}\chi_{orb}(\overline{\mathcal{J}}^d_{g,n}) = \sum_{(\Gamma, T) \in \widehat{G}(g,n)^0}\sum_{\lbrace T' \in \phi^{-1}((\Gamma,T))\rbrace}\frac{\prod_{v \in V(\Gamma)}\chi_{orb}(\mathcal{M}_{0,n(v)})}{|Aut(\Gamma,T)||\phi^{-1}(\Gamma,T)|} \\=\sum_{T' \in G(0, 2g+n)}\frac{\prod_{v \in V(T')}\chi_{orb}(\mathcal{M}_{0,n(v)})}{2^g(g!)}= \frac{\chi_{orb}(\overline{\mathcal{M}}_{0, 2g + n})}{2^g(g!)}.\end{align*}

Where in the last two equalities, we use the fact that $\overline{\mathcal{M}}_{0,2g+n}$ has a locally closed stratification $\overline{\mathcal{M}}_{0,2g+n} = \underset{T' \in G(0,2g+n)}{\bigsqcup}\mathcal{M}^{T'}$ and the fact that for $T' \in G(0,2g+n)$ , the automorphism group of T ^′ is trivial and therefore, the gluing morphism $\xi_{T'}\;:\; \prod_{v \in V(T')}\mathcal{M}_{0,n(v)} \rightarrow \mathcal{M}^{T'}$ is an isomorphism onto its image.

We conclude using the fact that $\overline{\mathcal{M}}_{0,2g+n}$ is a projective variety, hence its orbifold Euler characteristic is equal to its topological Euler characteristic.