Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-26T17:15:02.259Z Has data issue: false hasContentIssue false

On the derived Lusztig correspondence

Published online by Cambridge University Press:  07 March 2023

Gérard Laumon
Affiliation:
Université Paris-Saclay, LMO CNRS UMR 8628, France; E-mail: [email protected]
Emmanuel Letellier
Affiliation:
Université Paris Cité, IMJ-PRG CNRS UMR 7586, France; E-mail: [email protected]

Abstract

Let G be a connected reductive group, T a maximal torus of G, N the normalizer of T and $W=N/T$ the Weyl group of G. Let ${\mathfrak {g}}$ and ${\mathfrak {t}}$ be the Lie algebras of G and T. The affine variety $\mathfrak {car}={\mathfrak {t}}/\!/W$ of semisimple G-orbits of ${\mathfrak {g}}$ has a natural stratification

$$ \begin{align*} \mathfrak{car}=\coprod_{\lambda}\mathfrak{car}_{\lambda} \end{align*} $$

indexed by the set of G-conjugacy classes of Levi subgroups: the open stratum is the set of regular semisimple orbits and the closed stratum is the set of central orbits.

In [17], Rider considered the triangulated subcategory $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {g}}_{\mathrm {nil}}/G])^{\mathrm {Spr}}$ of $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {g}}_{\mathrm {nil}}/G])$ generated by the direct summand of the Springer sheaf. She proved that it is equivalent to the derived category of finitely generated dg modules over the smash product algebra ${\overline {\mathbb {Q}}_{\ell }}[W]\# H^{\bullet }_G(G/B)$ where $H^{\bullet }_G(G/B)$ is the G-equivariant cohomology of the flag variety. Notice that the later derived category is $D_{\mathrm {c}}^{\mathrm {b}}(\mathrm {B}(N))$ where $\mathrm {B}(N)=[\mathrm {Spec}(k)/N]$ is the classifying stack of N-torsors.

The aim of this paper is to understand geometrically and generalise Rider’s equivalence of categories: For each $\lambda $ we construct a cohomological correspondence inducing an equivalence of categories between $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {t}}_{\lambda }/N])$ and $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {g}}_{\lambda }/G])^{\mathrm {Spr}}$ .

Type
Algebra
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

1 Introduction

Let G be a connected reductive algebraic group over an algebraic closure k of a finite field. Let T be a maximal torus of G, and let B be the Borel subgroup of G containing T. We denote by N the normalizer of T in G, and we let $W=N/T$ be the Weyl group of G. We denote by ${\mathfrak {g}}$ , ${\mathfrak {t}}$ , and ${\mathfrak {b}}$ the Lie algebras of G, T and B, respectively, and we denote by ${\mathfrak {g}}_{\mathrm {nil}}$ the nilpotent cone of ${\mathfrak {g}}$ .

In [Reference Rider17], Rider considered the triangulated subcategory $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {g}}_{\mathrm {nil}}/G])^{\mathrm {Spr}}$ of $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {g}}_{\mathrm {nil}}/G])$ generated by the direct summand of the Springer sheaf. She proved that it is equivalent to the derived category of finitely generated dg modules over the smash product algebra ${\overline {\mathbb {Q}}_{\ell }}[W]\# H^{\bullet }_G(G/B)$ , where $H^{\bullet }_G(G/B)$ is the G-equivariant cohomology of the flag variety (see also [Reference Li12] for a similar result).

We denote by $\mathrm {B}(N)=[\mathrm {Spec}(k)/N]$ the classifying stack of N-torsors. Rider’s result can be then reformulated as an equivalence of categories between $D_{\mathrm {c}}^{\mathrm {b}}(\mathrm {B}(N))$ and $D_{\mathrm {c}}^{\mathrm {b}}([{\mathfrak {g}}_{\mathrm {nil}}/G])^{\mathrm {Spr}}$ . The aim of this paper is to construct this equivalence via a cohomological correspondence between $\mathrm {B}(N)$ and $[{\mathfrak {g}}_{\mathrm {nil}}/G]$ in the spirit of Lusztig induction. Namely, we construct a complex ${\overline {{\mathcal {N}}}}_{\mathrm {nil}}$ on $\mathrm {B}(N)\times [{\mathfrak {g}}_{\mathrm {nil}}/G]$ , such that the functor

$$ \begin{align*}D_{\mathrm{c}}^{\mathrm{b}}(\mathrm{B}(N))\rightarrow D_{\mathrm{c}}^{\mathrm{b}}([{\mathfrak{g}}_{\mathrm{nil}}/G])^{\mathrm{Spr}},\hspace{.5cm}K\mapsto \mathrm{pr}_{2*}\,\underline{\mathrm{Hom}}\left({\overline{{\mathcal{N}}}}_{\mathrm{nil}},\mathrm{pr}_1^!(K)\right) \\[-15pt]\end{align*} $$

is an equivalence of categories, where $\mathrm {pr}_1$ and $\mathrm {pr}_2$ are the two obvious projections.

Let us remark that $\mathrm {B}(N)$ and $[{\mathfrak {g}}_{\mathrm {nil}}/G]$ are the zero fibres of the canonical maps

$$ \begin{align*}[{\mathfrak{t}}/N]\rightarrow\mathfrak{car},\hspace{1cm}[{\mathfrak{g}}/G]\rightarrow\mathfrak{car}\\[-15pt] \end{align*} $$

where

$$ \begin{align*} \mathfrak{car}:={\mathfrak{t}}/\!/W=\mathrm{Spec}(k[{\mathfrak{t}}]^W).\\[-15pt] \end{align*} $$

In this paper we consider more generally the analogous equivalences above the strata of the natural stratification

$$ \begin{align*} \mathfrak{car}=\coprod_{\lambda\in\mathfrak{L}}\mathfrak{car}_{\lambda}\\[-15pt] \end{align*} $$

where $\mathfrak {L}$ is the set of G-conjugacy classes of Levi subgroups (of parabolic subgroups) of G.

We consider the quotient stacks

$$ \begin{align*} \mathcal{G}=[{\mathfrak{g}}/G],\hspace{0.5cm}\mathcal{B}= [{\mathfrak{b}}/B],\hspace{.5cm}\mathcal{T}=[{\mathfrak{t}}/T], \hspace{0.5cm}{\overline{\mathcal{T}}}=[{\mathfrak{t}}/N] \end{align*} $$

with respect to the adjoint actions $\mathrm {Ad}$ (which is trivial for T), and we denote by $\pi :\mathcal {T}\rightarrow {\overline {\mathcal {T}}}$ the induced map. Notice that our stacks are algebraic stacks over $\mathfrak {car}$ .

We consider the following commutative diagram:

(1.1)

where q is induced by the projection ${\mathfrak {b}}\rightarrow {\mathfrak {t}}$ , and p is induced by the inclusion ${\mathfrak {b}}\subset {\mathfrak {g}}$ .

We put

$$ \begin{align*} {\mathcal{N}}:=(q,p)_!{\overline{\mathbb{Q}}_{\ell}}. \end{align*} $$

The Lusztig induction and restriction functors are defined by

$$ \begin{align*} &\mathrm{Ind}:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{T})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}),\,\,\,\,\,K\mapsto p_*q^!K=\mathrm{pr}_{\mathcal{G}\, *}\underline{\mathrm{ Hom}}\left({\mathcal{N}},\mathrm{pr}_{\mathcal{T}}^!(K)\right)\\ &\mathrm{Res}:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{T}),\,\,\,\,\, K\mapsto q_!p^*K=\mathrm{pr}_{\mathcal{T}\, !}\left({\mathcal{N}}\otimes\mathrm{pr}_{\mathcal{G}}^*(K)\right) \end{align*} $$

For a stack $\mathcal {X}$ over $\mathfrak {car}$ , we put

$$ \begin{align*} \mathcal{X}_{\lambda}=\mathcal{X}\times_{\mathfrak{car}}\mathfrak{car}_{\lambda}. \end{align*} $$

We prove the following result (see Theorem 5.1).

Theorem 1.1 (Descent).

For $\lambda \in \mathfrak {L}$ , the restriction ${\mathcal {N}}_{\lambda }$ of ${\mathcal {N}}$ to $(\mathcal {T}\times _{\mathfrak {car}}\mathcal {G})_{\lambda }$ descends to ${\overline {{\mathcal {N}}}}_{\lambda }$ on $({\overline {\mathcal {T}}}\times _{\mathfrak {car}}\mathcal {G})_{\lambda }$ .

To prove the existence of ${\overline {{\mathcal {N}}}}_{\lambda }$ , we regard the complex $(q_{\lambda },p_{\lambda })_!{\overline {\mathbb {Q}}_{\ell }}$ , (where $(q_{\lambda },p_{\lambda })$ is obtained from $(q,p)$ by base change) as the outcome of a Postnikov diagram, which descends in a natural way to a Postnikov diagram on $({\overline {\mathcal {T}}}\times _{\mathfrak {car}}\mathcal {G})_{\lambda }$ using weight arguments. The complex ${\overline {{\mathcal {N}}}}_{\lambda }$ is then defined as the outcome of the descended Postnikov diagram.

Remark 1.2.

  1. (1) As a particular case, the restriction of ${\mathcal {N}}$ to $\mathrm {B}(T)\times [{\mathfrak {g}}_{\mathrm {nil}}/G]$ descends to a complex ${\overline {{\mathcal {N}}}}_{\mathrm { nil}}$ on $\mathrm {B}(N)\times [{\mathfrak {g}}_{\mathrm {nil}}/G]$ .

  2. (2) As noticed by S. Gunningham [Reference Gunningham6], the functor $\mathrm {Res}$ depends on the choice of the Borel subgroup containing T, and so the restriction of a complex $K\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G})$ cannot be W-equivariant. Therefore, we cannot expect that ${\mathcal {N}}$ descends to ${\overline {\mathcal {T}}}\times _{\mathfrak {car}}\mathcal {G}$ . In 5.4, we use an old computation of Verdier that explains more directly why ${\mathcal {N}}$ cannot descend. Therefore, the above descent result seems to be optimal.

  3. (3) We also prove that ${\mathcal {N}}$ descends over regular elements, which stratum intersects with all strata above $\mathfrak {car}$ (see §5.3).

For each $\lambda \in \mathfrak {L}$ we define the pair of adjoint functors $(\mathrm {R}_{\lambda },\mathrm {I}_{\lambda })$ by

$$ \begin{align*} &\mathrm{R}_{\lambda}:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}_{\lambda})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}({\overline{\mathcal{T}}}_{\lambda}),\hspace{.5cm}K\mapsto\mathrm{pr}_{1!}\left({\overline{{\mathcal{N}}}}_{\lambda}\otimes \mathrm{pr}_2^*(K)\right),\\ &\mathrm{I}_{\lambda}:D_{\mathrm{c}}^{\mathrm{b}}({\overline{\mathcal{T}}}_{\lambda})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}_{\lambda}),\hspace{.5cm}K\mapsto \mathrm{pr}_{2*}\,\underline{\mathrm{ Hom}}\left({\overline{{\mathcal{N}}}}_{\lambda},\mathrm{pr}_1^!(K)\right) \end{align*} $$

If $\mathrm {Ind}_{\lambda }$ and $\mathrm {Res}_{\lambda }$ denote the induction and restriction above $\mathfrak {car}_{\lambda }$ and $\pi _{\lambda }:\mathcal {T}_{\lambda }\rightarrow {\overline {\mathcal {T}}}_{\lambda }$ the morphism obtained by base change from $\pi $ , then

$$ \begin{align*}\mathrm{Res}_{\lambda}=\pi_{\lambda}^*\circ\mathrm{R}_{\lambda},\hspace{.5cm}\mathrm{Ind}_{\lambda}=\mathrm{I}_{\lambda}\circ\pi_{\lambda\,!}. \end{align*} $$

For each geometric point c of $\mathfrak {car}_{\lambda }$ , we have the functor

which is compatible by base change with the functors $\mathrm {Ind}_{\lambda }$ .

For each geometric point c of $\mathfrak {car}$ , we define $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {{Spr}}}$ as the triangulated subcategory of $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)$ generated by the direct factors of $\mathrm {Ind}_c({\overline {\mathbb {Q}}_{\ell }})$ . We then define $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}$ as the full subcategory of $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })$ of complexes K such that $K_c\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ for all geometric points c of $\mathfrak {car}_{\lambda }$ .

We prove the following theorem (see Theorem 7.7 and Remark 7.6):

Theorem 1.3. The functor $\mathrm {I}_{\lambda }$ induces an equivalence of categories $D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\lambda })\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}$ with inverse given by $\mathrm {R}_{\lambda }$ .

If G is of type A with connected center, then $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}=D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })$ , and so $\mathrm {I}_{\lambda }:D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\lambda })\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })$ is an equivalence of categories with inverse functor $\mathrm {R}_{\lambda }$ .

Remark 1.4.

  1. (1) Notice that the stack $\overline {\mathcal {T}_c}$ with $c=0$ is $\mathrm {B}(N)=[\mathrm {Spec}(k)/N]$ . It follows from Theorem 1.3 that the category $D_{\mathrm {c}}^{\mathrm {b}}(\mathrm {B}(N))$ is equivalent to $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_0)^{\mathrm {Spr}}$ .

  2. (2) When $\lambda $ is the stratum of semisimple regular elements, the two stacks ${\overline {\mathcal {T}}}_{\lambda }$ and $\mathcal {G}_{\lambda }$ are isomorphic, and the functors $\mathrm {I}_{\lambda }$ , $\mathrm {R}_{\lambda }$ are the identity functors (see §6.2).

  3. (3) The interested reader may follow the methods of [Reference Beilinson, Bernstein and Deligne2 Reference Beilinson, Bernstein and Deligne, §6] to get similar results over the complex numbers.

Consider the projection

The functor $s^![\mathrm {dim}\, T](\mathrm {dim}\, T)$ is an equivalence $\mathcal {M}({\mathfrak {t}})\rightarrow \mathcal {M}(\mathcal {T})$ between the categories of perverse sheaves. Therefore, when working with perverse sheaves, we may work with the diagram

which is more convenient, as the kernel $(q',p)_!{\overline {\mathbb {Q}}_{\ell }}$ is the intersection cohomology complex of ${\mathfrak {t}}\times _{\mathfrak {car}}\mathcal {G}$ , and so it descends naturally to $[{\mathfrak {t}}/W]\times _{\mathfrak {car}}\mathcal {G}$ . Moreover, by Bezrukavnikov and Yom Din [Reference Bezrukavnikov and Yom Din3], the functor $\mathrm {Ind}$ and $\mathrm {Res}$ maps perverse sheaves to perverse sheaves.

The above factorization of p via $(q',p)$ and its generalisation in the framework of the generalised Springer correspondence is due to Lusztig (see [Reference Letellier11, Proof of Proposition 5.5.3] for more details and [Reference Lusztig15] for the case where G is not necessarily connected).

In §2.9, we define a pair of adjoint functors ${^p}\mathrm {I}:\mathcal {M}([{\mathfrak {t}}/W])\rightarrow \mathcal {M}(\mathcal {G})$ , and ${^p}\mathrm {R}:\mathcal {M}(\mathcal {G})\rightarrow \mathcal {M}([{\mathfrak {t}}/W])$ and we prove the following theorem (see Theorem 7.10).

Theorem 1.5. The functor ${^p}\mathrm {I}$ induces an equivalence of categories $\mathcal {M}([{\mathfrak {t}}/W])\rightarrow \mathcal {M}(\mathcal {G})^{\mathrm {Spr}}$ with inverse functor ${^p}\mathrm {R}$ . In particular, if G is of type A with connected center, then $\mathcal {M}(\mathcal {G})^{\mathrm {Spr}}=\mathcal {M}(\mathcal {G})$ , and so the categories $\mathcal {M}([{\mathfrak {t}}/W])$ and $\mathcal {M}(\mathcal {G})$ are equivalent.

This result is an analogue in the $\ell $ -adic setting of (a special case of) the main result of S. Gunningham [Reference Gunningham7] in the D-module setting. We were informed by the anonymous referee that, using the result of Bezrukavnikov and Yom Din, the proof of Gunningham works also in the $\ell $ -adic setting (although this is not published).

2 Preliminaries

2.1 Postnikov diagrams in triangulated categories

Let ${\mathcal {D}}$ be a triangulated category. We will need the following lemma:

Lemma 2.1. Consider a diagram in ${\mathcal {D}}$

where $(u,v,w)$ and $(u',v',w')$ are distinguished triangles. Suppose that

$$ \begin{align*}\mathrm{Hom}(B,A')=0,\hspace{.5cm}\text{ and }\hspace{.5cm}\mathrm{Hom}(A,B'[-1])=0. \end{align*} $$

Then there exists a unique morphism $C\rightarrow C'$ which extends the above diagram into a morphism of distinguished triangles.

Proof. Only the unicity needs to be proved (the existence follows from the axioms of a triangulated category). We are thus reduced to prove that if we have a morphism of triangles,

then $\beta =0$ .

As $\beta \circ u=0$ , there exists $\gamma :A\rightarrow C'$ such that $\gamma \circ v=\beta $ . Since

$$ \begin{align*}v'\circ\gamma\circ v=0 \end{align*} $$

there exists $\varepsilon :B\rightarrow A'$ such that $v'\circ \gamma =\varepsilon \circ w$ . By assumption, $\varepsilon =0$ and so $v'\circ \gamma =0$ .

There exists thus $\overline {\gamma }:A\rightarrow B'[-1]$ such that $u'\circ \overline {\gamma }=\gamma $ . By assumption, we must have $\overline {\gamma }=0$ , and so $\gamma =0$ from which we get that $\beta =0$ .

A Postnikov diagram $\Lambda $ [Reference Orlov16] consists of a complex

in ${\mathcal {D}}$ , called the base and denoted by $\Lambda _b$ , together with a finite sequence of distinguished triangles

with $i=1,\dots ,m$ , such that $\partial _i=\alpha _{i-1}\circ d_i$ for all i. We visualize $\Lambda $ as

(2.1)

The length of $\Lambda $ is the integer m.

The object $C_m$ will be called the outcome of the Postnikov diagram $\Lambda $ .

Notice that if ${\mathcal {D}}$ is equipped with a nondegenerate t-structure, then we can define the Postnikov diagram $\Lambda (K)$ with outcome K for any complex $K\in {\mathcal {D}}^{[n,n+m]}$ as

(2.2)

using the distinguished triangles

The construction of $\Lambda (K)$ is functorial in K.

Remark 2.2. Given $K\in {\mathcal {D}}^{[n,n+m]}$ , then $\Lambda (K)$ is the unique (up to a unique isomorphism) Postnikov diagram of the form (2.1) with outcome K such that

(2.3) $$ \begin{align} C_i\in{\mathcal{D}}^{\leq n-m+2i}\hspace{1cm}\text{and}\hspace{1cm} A_i\in {\mathcal{D}}^{\geq n-m+2i} \end{align} $$

for all $i=1,\dots ,m$ . This follows from [Reference Beilinson, Bernstein and Deligne2, Proposition 1.3.3(ii)].

Lemma 2.3. Given $K\in {\mathcal {D}}^{[n,n+m]}$ , the Postnikov diagram $\Lambda (K)$ is the unique one (up a unique isomorphism) that completes the subdiagram

Proof. By Remark 2.2, it is enough to prove that if we are given a Postnikov diagram of the form (2.1) where $A_i=P_i[m-n-2i]$ with $P_i$ a perverse sheaf, then $C_i\in {\mathcal {D}}^{[i-(m-n),2i-(m-n)]}$ for all $i=1,\dots ,m$ . The proof goes by recurrence on $m\geq 1$ using the long exact sequence of perverse cohomology.

Lemma 2.4. Assume that we have a Postnikov diagram with the notation as in diagram (2.1) and that for each $i=0,\dots ,m-2$ , any $j\geq i+2$ and any $k\geq 1$ we have

$$ \begin{align*}\mathrm{Hom}(A_j,A_i[-k])=0. \end{align*} $$

Then if $(d^{\prime }_m,d^{\prime }_{m-1},\dots ,d^{\prime }_1)$ is a sequence of arrows $d^{\prime }_i:A_i\rightarrow C_{i-1}$ such that $\partial _i=\alpha _{i-1}\circ d^{\prime }_i$ for all i, then

$$ \begin{align*}(d^{\prime}_m,\dots,d^{\prime}_1)=(d_m,\dots,d_1). \end{align*} $$

Proof. We need to prove that

$$ \begin{align*}\mathrm{Hom}(A_{i+2},C_i[-1])=0 \end{align*} $$

for all $i=0,\dots ,m-2$ .

Since we have a distinguished triangle

we have an exact sequence

By assumption, the right-hand side is $0$ , and so we are reduced to prove that

$$ \begin{align*}\mathrm{Hom}(A_{i+2},C_{i-1}[-2])=0. \end{align*} $$

Repeating the argument as many times as needed, we end up proving that $\mathrm {Hom}(A_{i+2},C_0[-1-i])=0$ , which follows also from the assumption as $C_0=A_0$ .

Proposition 2.5. Assume given a complex $\Lambda _b$ in ${\mathcal {D}}$

(2.4)

and suppose that it satisfies

(2.5) $$ \begin{align} \mathrm{Hom}(A_j,A_i)=0,\hspace{.5cm}\text{ for all } j<i, \end{align} $$

and

(2.6) $$ \begin{align} \mathrm{Hom}(A_j,A_i[-k])=0,\hspace{.5cm}\text{ for all }j>i\text{ and } k\geq 1. \end{align} $$

Then the complex (2.4) can be completed in a unique way (up to a unique isomorphism) into a Postnikov diagram $\Lambda $ in ${\mathcal {D}}$ .

Proof. The proof goes by induction on $0\leq r <m$ . If $r=0$ , then this is obvious. Suppose that we have proved the proposition up to the rank r. Therefore, we have the complex $C_r$ . By Lemma 2.4, there exists a unique map $d_{r+1}$ such that the following diagram commutes:

We complete $d_{r+1}$ into a distinguished triangle

Now we notice that

$$ \begin{align*}\mathrm{Hom}(A_{r+1},C_r[-1])=0,\hspace{.5cm}\text{ and }\hspace{.5cm}\mathrm{Hom}(C_r,A_{r+1})=0. \end{align*} $$

Indeed, the complexes $C_r$ being successive extensions of the complexes $A_i$ , with $i=0,\dots ,r$ , this follows from the assumptions (2.5) and (2.6) .

By Lemma 2.1, such a $C_{r+1}$ is thus unique (up to a unique isomorphism).

2.2 Stacks and sheaves: notation and convention

Let k be an algebraic closure of a finite field. In these notes, unless specified, our stacks are k-algebraic stacks of finite type, and quotient stacks are denoted by $[X/G]$ if G is an algebraic group over k acting a k-scheme X. If $X=\mathrm {Spec}(k)$ , we put $\mathrm {B}(G)=[X/G]$ .

For a morphism $f:\mathcal {X}\rightarrow {\mathcal {Y}}$ of stacks, we have the usual functors

$$ \begin{align*}f_*=Rf_*:D_{\mathrm{c}}^+(\mathcal{X})\rightarrow D_{\mathrm{c}}^+({\mathcal{Y}}),\hspace{1cm} f_!=Rf_!:D_{\mathrm{c}}^-(\mathcal{X})\rightarrow D_{\mathrm{c}}^-({\mathcal{Y}}),\end{align*} $$
$$ \begin{align*}f^*, f^!:D_{\mathrm{c}}^{\bullet}({\mathcal{Y}})\rightarrow D_{\mathrm{c}}^{\bullet}(\mathcal{X}),\hspace{.5cm}(\text{with } \bullet\in\{\emptyset,-,+,b\}) \end{align*} $$

between derived categories of constructible ${\overline {\mathbb {Q}}_{\ell }}$ -sheaves (see [Reference Laszlo and Olsson9]).

Remark 2.6. The fact that $f^!$ preserves $-,+,b$ follows from from our assumption that our stacks are of finite type over a field. Indeed, the statement reduces to the case where $\mathcal {X}$ and ${\mathcal {Y}}$ are schemes of finite type over a field which is known [Reference Deligne5, Corollary 2.9].

We will use freely the properties of these functors (adjunction, projection formula, base change,…). When there is no ambiguity, we will sometimes write $K|_{\mathcal {X}}$ instead of $f^*(K)$ .

Remark 2.7.

  1. (i) Notice that if $d\in \mathbb {Z}$ is the dimension of a fibre of f whose absolute value is maximal, then

    $$ \begin{align*}f_!:D_{\mathrm{c}}^{]-\infty,n]}(\mathcal{X})\rightarrow D_{\mathrm{c}}^{]-\infty,n+2d]}({\mathcal{Y}}). \end{align*} $$

    For instance

    $$ \begin{align*}H_c^i([X/G],{\overline{\mathbb{Q}}_{\ell}})=0\hspace{.5cm} \text{ if }\hspace{.5cm}i> 2(\mathrm{dim}\, X-\mathrm{dim}\, G). \end{align*} $$
  2. (ii) If f is representable, then $f_!$ induces

    $$ \begin{align*}f_!:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}({\mathcal{Y}}). \end{align*} $$
  3. (iii) If f is smooth with fibres of pure relative dimension d, then [Reference Laszlo and Olsson9, 9.1.2]

    $$ \begin{align*}f^!=f^*[2d](d). \end{align*} $$

Except in some rare occasions, we will only need the category $D_{\mathrm {c}}^{\mathrm {b}}$ .

We will denote by $\overline {\mathbb {Q}}_{\ell ,\, \mathcal {X}}$ the constant sheaf on $\mathcal {X}$ . If there are no ambiguities, we will sometimes denote it simply by ${\overline {\mathbb {Q}}_{\ell }}$ to alleviate the notation.

For two ${\mathcal {Y}}$ -stacks $\mathcal {X}$ and $\mathcal {X}'$ , we define the external tensor product of $K\in D_{\mathrm {c}}^-(\mathcal {X})$ and $K'\in D_{\mathrm {c}}^-(\mathcal {X}')$ above ${\mathcal {Y}}$ as

$$ \begin{align*}K\boxtimes_{\mathcal{Y}} K':=\mathrm{pr}_1^*K\otimes\mathrm{pr}_2^*K'\in D_{\mathrm{c}}^-(\mathcal{X}\times_{\mathcal{Y}}\mathcal{X}'). \end{align*} $$

where $\mathrm {pr}_1$ and $\mathrm {pr}_2$ are the two projections.

We consider the auto-dual perversity p and we denote by $\mathcal {M}(\mathcal {X})$ the full subcategory of $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ of perverse sheaves on $\mathcal {X}$ . Then, if $\mathcal {X}$ is an equidimensional stack with smooth dense open substack ${\mathcal {U}}$ , the intersection cohomology complex on $\mathcal {X}$ with coefficient in a local system $\mathcal {E}$ on U is denoted by ${\mathrm {IC}}_{\mathcal {X}}(\mathcal {E})$ ;its restriction to ${\mathcal {U}}$ is $\mathcal {E}$ . If $\mathcal {E}={\overline {\mathbb {Q}}_{\ell }}$ , we will simply write ${\mathrm {IC}}_{\mathcal {X}}$ instead of ${\mathrm {IC}}_{\mathcal {X}}({\overline {\mathbb {Q}}_{\ell }})$ . Recall that ${\mathrm {IC}}_{\mathcal {X}}(\mathcal {E})[\mathrm {dim}\,\mathcal {X}]\in \mathcal {M}(\mathcal {X})$ is the image of

$$ \begin{align*}{^p}{\mathcal{H}}^0(j_!\mathcal{E}[\mathrm{dim}\,\mathcal{X}])\rightarrow {^p}{\mathcal{H}}^0(j_*\mathcal{E}[\mathrm{dim}\,\mathcal{X}]), \end{align*} $$

where $j:{\mathcal {U}}\rightarrow \mathcal {X}$ is the inclusion. Recall also that if $\mathcal {X}'\rightarrow \mathcal {X}$ is a small resolution of singularities (representable, proper, birational, $\mathcal {X}'$ smooth), then $f_*{\overline {\mathbb {Q}}_{\ell }}={\mathrm {IC}}_{\mathcal {X}}$ .

If $D_{\mathcal {X}}$ denotes the Verdier dual, then $D_{\mathcal {X}}({\mathrm {IC}}_{\mathcal {X}}(\mathcal {E}))={\mathrm {IC}}_{\mathcal {X}}(\mathcal {E}^{\vee })[2\mathrm {dim}(\mathcal {X})](\mathrm {dim}(\mathcal {X}))$ , where $\mathcal {E}^{\vee }$ denotes the dual local system.

Proposition 2.8. Let $\mathcal {X}$ be an equidimensional algebraic stack, and let ${\mathcal {U}}$ be a dense open smooth substack of $\mathcal {X}$ . Suppose that we have a short exact sequence

in the category of perverse sheaves on $\mathcal {X}$ . If both $A'$ and $A"$ are the intermediate extension of their restriction to ${\mathcal {U}}$ , then A is also the intermediate extension of its restriction to ${\mathcal {U}}$ .

Proof. Let j be the inclusion of ${\mathcal {U}}$ in $\mathcal {X}$ . From $j_!j^*\rightarrow 1\rightarrow j_*j^*$ and the fact that A is a perverse sheaf, we have a commutative diagram:

from which we can identify $j_{!*}j^*A$ as a subquotient of A. In particular,

$$ \begin{align*}\mathrm{length}(j_{!*}j^*A)\leq \mathrm{length}(A). \end{align*} $$

It is thus enough to prove that

(2.7) $$ \begin{align} \mathrm{length}(j_{!*}j^*A)\geq \mathrm{length}(A). \end{align} $$

We have the commutative diagram of perverse sheaves

where the top and bottom horizontal sequences are exact. We thus deduce that the middle sequence is exact at $A'$ and $A"$ and the composition $A'\rightarrow A"$ is zero, from which we deduce the inequality (2.7) as

$$ \begin{align*} \mathrm{length}(A)=\mathrm{length}(A')+\mathrm{length}(A").\\[-36pt] \end{align*} $$

As we assume that k is the algebraic closure of a finite field and that all our stacks are of finite type, any stack we consider in this paper will be defined over some finite subfield of k.

If $\mathcal {X}$ is defined over finite subfield $k_o\subset k$ , we denote by $\mathcal {X}_o$ the corresponding $k_o$ -structure on $\mathcal {X}$ (if no confusion arises) and we denote by $\mathrm {Frob}_o:\mathcal {X}\rightarrow \mathcal {X}$ the induced geometric Frobenius on $\mathcal {X}$ .

Let $K,K'\in D_{\mathrm {c}}^b(\mathcal {X})$ . We recall that $H_c^i(\mathcal {X},K)$ (resp. $\mathrm {Ext}^i(K,K')=\mathrm {Hom}(K,K'[i])$ ) is said to be pure of weight r if there exists a finite subfield $k_o$ of k such that $\mathcal {X}$ and K (resp. K and $K'$ ) are defined over $k_o$ , and the eigenvalues of the induced automorphism $\mathrm {Frob}_o^*$ on $H_c^i(\mathcal {X},K)$ (resp. $\mathrm {Ext}^i(K,K')$ ) are algebraic numbers whose complex conjugates are all of absolute value $|k_o|^{r/2}$ . It is well known that this notion of weight does not depend on the choice of $k_o$ . In particular, the Tate twist ${\overline {\mathbb {Q}}_{\ell }}(i)$ makes sense over k.

Let $\mathcal {X}_o$ be a $k_o$ -structure on $\mathcal {X}$ and $K_o, K^{\prime }_o\in D_{\mathrm {c}}^b(\mathcal {X}_o)$ , and let us denote by K and $K'$ the induced complexes in $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ . Then the following sequence [Reference Beilinson, Bernstein and Deligne2, (5.1.2.5)]

(2.8)

is exact for all i.

Notice that if $\mathrm {Ext}^j(K,K')=0$ for odd values of j, then it follows from the above exact sequence that for all i,

$$ \begin{align*}\mathrm{Ext}^{2i}(K_o,K^{\prime}_o)\rightarrow\mathrm{Ext}^{2i}(K,K')^{\mathrm{Frob}_o} \end{align*} $$

is an isomorphism.

2.3 Cohomology of $\mathrm {B}(T)$

Let T be a rank d torus over k. Recall that for any k-scheme S, the category $\mathrm {B}(T)(S)$ is the category of T-torsors over S, and the algebraic stack $\mathrm {B}(T)$ is of dimension $-d$ .

The cohomology $H^{\bullet }(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})$ is concentrated in nonnegative even degrees, and the morphism

$$ \begin{align*}c_{\mathrm{can}}:X^*(T)\rightarrow H^2(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})(1) \end{align*} $$

given by Chern classes induces an isomorphism

$$ \begin{align*}X^*(T)\otimes {\overline{\mathbb{Q}}_{\ell}}(-1)\simeq H^2(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

As ${\overline {\mathbb {Q}}_{\ell }}$ -algebras, $H^{2\bullet }(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})$ is isomorphic to $\mathrm {Sym}^{\bullet }\big (X^*(T)\otimes {\overline {\mathbb {Q}}_{\ell }}(-1)\big )$ .

By duality, $H_c^{\bullet }(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})$ is thus concentrated in even degrees $\leq -2\,\mathrm {dim}(T)$ , and $H_c^{2i}(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})$ is pure of weight $2i$ .

2.4 W-equivariant complexes

Let W be a finite group and a stack $\mathcal {X}$ . An action of W on a complex $K\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ is a group homomorphism

$$ \begin{align*}\theta: W\longrightarrow \mathrm{Aut}(K).\\[-15pt] \end{align*} $$

In this case we define the W-invariant part $K^W\rightarrow K$ in $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ of $(K,\theta )$ as follows.

Notice first that in any additive category, if for some morphism $e:A\rightarrow A$ , there exist two morphisms $u:A\rightarrow A'$ and $v:A'\rightarrow A$ such that $v\circ u=e$ and $u\circ v=1_{K'}$ (in which case e is an idempotent which is said to be split), then $1-e$ admits a kernel which is v and a cokernel which is u. In particular, $(A',u,v)$ is unique up to a unique isomorphism and we call it the splitting of e.

Since $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ is a triangulated category with bounded t-structure, by the main theorem of [Reference Le and Chen10], every idempotent element e of $\mathrm {End}(K)$ splits. Considering the indempotent

(2.9) $$ \begin{align} e=e_K:=\frac{1}{|W|}\sum_{w\in W}\theta(w)\in\mathrm{End}(K),\\[-15pt]\nonumber \end{align} $$

we define $K^W\rightarrow K$ as the kernel of $1-e$ .

A W-torsor is a morphism of stacks $\pi :\mathcal {X}\rightarrow \overline {\mathcal {X}}$ that fits to a cartesian diagram

(2.10)

Remark 2.9. (1) A W-torsor $\pi :\mathcal {X}\rightarrow \overline {\mathcal {X}}$ is thus finite étale representable and for any scheme S and morphism $S\rightarrow {\mathcal {Y}}$ , the projection

$$ \begin{align*}S\times_{\overline{\mathcal{X}}}\mathcal{X}\rightarrow S\\[-15pt] \end{align*} $$

has a natural structure of W-torsor (between schemes).

(2) If $\pi :\mathcal {X}\rightarrow \overline {\mathcal {X}}$ is a W-torsor, then $\mathcal {X}$ is equipped with a right action of W in the sense of [Reference Romagny18] and conversely, from right action of W on $\mathcal {X}$ we get a W-torsor by taking the quotient morphism of $\mathcal {X}$ by W. However, although this is implicit, we will not use the definition of group actions on stacks or the notion of quotient of stacks by group action.

An $\ell $ -adic sheaf on $\mathrm {B}(W)$ is a vector space equipped with a right action of W and

$$ \begin{align*}(\pi_o)_*{\overline{\mathbb{Q}}_{\ell}}={\overline{\mathbb{Q}}_{\ell}}[W]\\[-15pt] \end{align*} $$

for right multiplication of W on itself. The left multiplication corresponds to the Galois action. We thus have a decomposition

$$ \begin{align*}(\pi_o)_*{\overline{\mathbb{Q}}_{\ell}}=\bigoplus_{\chi} V_{\chi}\otimes \mathcal{L}_{o,\chi}\\[-15pt] \end{align*} $$

where the sum is over the irreducible ${\overline {\mathbb {Q}}_{\ell }}$ -characters of W, $V_{\chi }$ is a W-module affording the character $\chi $ and $\mathcal {L}_{o,\chi }$ is the irreducible smooth $\ell $ -adic sheaf on $\mathrm {B}(W)$ corresponding to $V_{\chi }^*$ .

By base change from Diagram (2.10) we get the analogous decomposition

(2.11) $$ \begin{align} \pi_*{\overline{\mathbb{Q}}_{\ell}}=\bigoplus_{\chi} V_{\chi}\otimes \mathcal{L}_{\chi} \end{align} $$

Notice that $\mathcal {L}_{\chi }$ may not be irreducible and that $(\pi _*{\overline {\mathbb {Q}}_{\ell }})^W={\overline {\mathbb {Q}}_{\ell }}$ .

Given a W-torsor $\pi :\mathcal {X}\rightarrow \overline {\mathcal {X}}$ , we denote by $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X},W)$ the subcategory of $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ whose objects are isomorphic to objects of the form $\pi ^*(\overline {K})$ with $\overline {K}\in D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})$ and morphisms are given by

$$ \begin{align*}\mathrm{Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X},W)}(\pi^*\overline{A},\pi^*\overline{B}):=\pi^*\mathrm{ Hom}(\overline{A},\overline{B})\simeq \mathrm{Hom}(\overline{A},\overline{B}). \end{align*} $$

We call $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X},W)$ the category of W-equivariant complexes on $\mathcal {X}$ (with respect to $\pi $ ).

Remark 2.10. The inverse functor of $\pi ^*:D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X},W)$ is given by

$$ \begin{align*}D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X},W)\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\overline{\mathcal{X}}),\hspace{.5cm}K\mapsto (\pi_*K)^W. \end{align*} $$

Indeed this follows from the above discussion and

$$ \begin{align*}\pi_*\pi^*\overline{K}=(\pi_*{\overline{\mathbb{Q}}_{\ell}})\otimes\overline{K} \end{align*} $$

which is a consequence of the projection formula.

Given two W-equivariant complexes $A=\pi ^*\overline {A}$ and $B=\pi ^*\overline {B}$ in $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ , we define an action of W on $\mathrm { Hom}_{D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})}(A,B)$ as follows.

We have

$$ \begin{align*} \mathrm{Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X})}(A,B)&=\mathrm{ Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X})}(\pi^*\overline{A},\pi^*\overline{B})\\ &=\mathrm{Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\overline{\mathcal{X}})}(\overline{A},\pi_*\pi^*\overline{B})\\ &= \bigoplus_{\chi} V_{\chi}\otimes\mathrm{Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\overline{\mathcal{X}})}\left(\overline{A}, \mathcal{L}_{\chi}\otimes\overline{B}\right). \end{align*} $$

The action of W on the $V_{\chi }$ defines thus an action of W on $\mathrm { Hom}_{D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})}(A,B)$ , and we have

$$ \begin{align*}\mathrm{Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X})}(A,B)^W=\mathrm{ Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{X},W)}(A,B). \end{align*} $$

Remark 2.11. Our definition of W-equivariant complexes is consistent with the usual one. If W acts (on the right) on a scheme X, then following [Reference Kiehl and Weissauer8, III, 15], a W-equivariant complex on X is a pair $(K,\theta )$ with $K\in D_{\mathrm {c}}^{\mathrm {b}}(X)$ and $\theta =(\theta _w)_{w\in W}$ a collection of isomorphisms

$$ \begin{align*}\theta_w:w^*(K)\rightarrow K \end{align*} $$

such that

  1. (i) $\theta _{ww'}=\theta _w\circ w^*(\theta _{w'})$ for all $w,w'\in W$ , and

  2. (ii) $\theta _1=1_K$ ,

where $1_K:K\rightarrow K$ denotes the identity morphism.

Moreover, if $(K,\theta ),(K',\theta ')\in D_{\mathrm {c}}^{\mathrm {b}}(X,W)$ , then the group W acts (on the left) on $\mathrm {Hom}_{D_{\mathrm {c}}^{\mathrm {b}}(X)}(K,K')$ as

$$ \begin{align*}w\cdot f=\theta^{\prime}_w\circ w^*(f)\circ(\theta_w)^{-1} \end{align*} $$

for all $w\in W$ and $f\in \mathrm {Hom}(K,K')$ , and

$$ \begin{align*}\mathrm{Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(X,W)}(K,K'):=\mathrm{ Hom}_{D_{\mathrm{c}}^{\mathrm{b}}(X)}(K,K')^W. \end{align*} $$

A commutative diagram

where $\pi $ and $\pi '$ are W-torsors, induces a functor $f^*:D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X}',W)\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X},W)$ , and, moreover, if the above diagram is cartesian and f is representable, then we also get a functor $f_!:D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X},W)\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X}',W)$ . Both are compatible with the usual functors $f^*$ and $f_!$ where we forget the actions of W.

Remark 2.12. Notice that if K is W-equivariant, then its Postnikov diagram $\Lambda (K)$ is W-equivariant (i.e., the vertices and the arrows of the diagram are W-equivariant).

In the next two following lemmas we assume given a W-torsor

$$ \begin{align*}\pi:\mathcal{X}\rightarrow\overline{\mathcal{X}}. \end{align*} $$

Lemma 2.13. Assume that we have a distinguished triangle

in $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ and that d is W-equivariant. Then there exists a distinguished triangle

(2.12)

in $D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})$ and an isomorphism of triangles

If, moreover, we assume that

$$ \begin{align*}\mathrm{Hom}(A,C[-1])=0 \hspace{.5cm}\text{ and }\hspace{.5cm}\mathrm{Hom}(C,A)=0, \end{align*} $$

then the triangle (2.12) is unique (up to a unique isomorphism), and the morphism s is unique.

Proof. As $d:\pi ^*\overline {A}\rightarrow \pi ^*\overline {C}$ is W-equivariant, by definition it descends to a unique morphism $\overline {d}:\overline {A}\rightarrow \overline {C}$ in $D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})$ . We complete this morphism into a distinguished triangle

in $D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})$ .

There exists an isomorphism $s:C'\rightarrow \pi ^*(\overline {C}')$ , such that the following diagram commutes:

The second statement follows from Lemma 2.1.

Proposition 2.14. Assume that we have a Postnikov diagram $\Lambda $ of the form (2.1) in $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ , such that the complex $\Lambda _b$ is the image by $\pi ^*$ of a complex

(2.13)

in $D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})$ . Suppose also that

(2.14) $$ \begin{align} \mathrm{Hom}(A_j,A_i)=0,\hspace{.5cm}\text{ for all } j<i, \end{align} $$

and

(2.15) $$ \begin{align} \mathrm{Hom}(A_j,A_i[-k])=0,\hspace{.5cm}\text{ for all }j>i\text{ and } k\geq 1. \end{align} $$

Then the complex (2.13) can be completed in a unique way (up to a unique isomorphism) into a Postnikov diagram $\overline {\Lambda }$ in $D_{\mathrm {c}}^{\mathrm {b}}(\overline {\mathcal {X}})$ , such that

$$ \begin{align*}\pi^*(\overline{\Lambda})\simeq\Lambda. \end{align*} $$

Proof. The conditions (2.14) and (2.15) imply the analogous conditions with $A_i$ replaced by $\overline {A}_i$ . Therefore, by Lemma 2.5 we can extend in a unique way the complex (2.13) into a Postnikov diagram $\overline {\Lambda }$ . We prove by induction on $0\leq r <m$ that $\pi ^*(\overline {\Lambda })=\Lambda $ using Lemma 2.13 and the unicity of $d_{r+1}$ (Lemma 2.4).

2.5 Cohomological correspondences

By a cohomological correspondence $\Gamma =({\mathcal {C}},N,p,q)$ we shall mean a correspondence of S-algebraic stacks

(2.16)

together with a kernel $N\in D_{\mathrm {c}}^-({\mathcal {C}})$ .

The correspondence $\Gamma $ comes with a functor

$$ \begin{align*}\mathrm{Res}=\mathrm{Res}_{\Gamma}:D_{\mathrm{c}}^-(\mathcal{X})\rightarrow D_{\mathrm{c}}^-({\mathcal{Y}}),\hspace{.5cm}A\mapsto q_!(N\otimes p^*A) \end{align*} $$

which we call the restriction functor associated to $\Gamma $ , whose right adjoint is the induction functor

$$ \begin{align*}\mathrm{Ind}=\mathrm{Ind}_{\Gamma}:D_{\mathrm{c}}^+({\mathcal{Y}})\rightarrow D_{\mathrm{c}}^+(\mathcal{X}),\hspace{.5cm}B\mapsto p_*\underline{\mathrm{Hom}}(N,q^!B). \end{align*} $$

Lemma 2.15. If we have a morphism of correspondences $f:({\mathcal {C}},p,q)\rightarrow ({\mathcal {C}}',p',q')$ (i.e., a commutative diagram)

(2.17)

then we have natural isomorphisms

$$ \begin{align*}\mathrm{Res}_{({\mathcal{C}},N,p,q)}=\mathrm{Res}_{({\mathcal{C}}',f_! N,p',q')},\hspace{1cm}\mathrm{Ind}_{({\mathcal{C}},N,p,q)}=\mathrm{Ind}_{({\mathcal{C}}',f_!N,p',q')}.\end{align*} $$

Proof. This is an obvious consequence of the projection formulas (see [Reference Laszlo and Olsson9, 9.1.1 and 9.1.i]).

Lemma 2.16 (Composition).

Assume that we have two cohomological correspondences $\Gamma =({\mathcal {C}},N,p,q)$ and $\Gamma '=({\mathcal {C}}',N',p',q')$ . Consider the following diagram:

Then

$$ \begin{align*}\mathrm{Res}_{\Gamma'}\circ\mathrm{Res}_{\Gamma}=\mathrm{Res}_{\Gamma'\circ\Gamma} \end{align*} $$

where

$$ \begin{align*}\Gamma'\circ\Gamma:=\left(\mathcal{Z}\times_S\mathcal{X},(q',p)_!(N'\boxtimes_{\mathcal{Y}} N),\overline{\mathrm{pr}}_2,\overline{\mathrm{pr}}_1\right). \end{align*} $$

We keep the correspondence (2.16), and we assume that it can be completed into a diagram

where $\pi $ and $\rho $ are W-torsors and where the square is cartesian.

If N is W-equivariant (i.e., descends to a complex $\overline {N}$ on $\overline {{\mathcal {C}}}$ ), then we have the following factorization

(2.18) $$ \begin{align} \mathrm{Ind}=\mathrm{I}\circ\pi_*,\hspace{1cm}\mathrm{Res}=\pi^*\circ\mathrm{R} \end{align} $$

where $\mathrm {I}:D_{\mathrm {c}}^+(\overline {{\mathcal {Y}}})\rightarrow D_{\mathrm {c}}^+(\mathcal {X})$ and $\mathrm {R}:D_{\mathrm {c}}^-(\mathcal {X})\rightarrow D_{\mathrm {c}}^-(\overline {{\mathcal {Y}}})$ are respectively the induction and restriction functors defined from the correspondence $(\overline {{\mathcal {C}}},\overline {N},\overline {p},\overline {q})$ .

Remark 2.17. Notice that $\mathrm {I}$ can be computed as

$$ \begin{align*}\mathrm{I}(\overline{K})=\mathrm{Ind}(\pi^*\overline{K})^W \end{align*} $$

since

$$ \begin{align*} \mathrm{Ind}(\pi^*\overline{K})&=\mathrm{I}\circ\pi_*\circ\pi^*(\overline{K})\\ &=\bigoplus_{\chi} V_{\chi}\otimes \mathrm{I}(\mathcal{L}_{\chi}\otimes \overline{K}), \end{align*} $$

where $\pi _*{\overline {\mathbb {Q}}_{\ell }}=\bigoplus _{\chi } V_{\chi }\otimes \mathcal {L}_{\chi }$ is the decomposition indexed by the irreducible characters of W (see Remark 2.10).

2.6 Reductive groups

For an affine connected algebraic group H over k, we denote by $\mathfrak {h}$ the Lie algebra of H. We denote by $Z(H)$ the center of H and by $z(\mathfrak {h})$ the center of $\mathfrak {h}$ . We will also denote by ${\mathcal {H}}:=[\mathfrak {h}/H]$ the quotient stack of $\mathfrak {h}$ by H for the adjoint action $\mathrm {Ad}:H\rightarrow \mathrm {GL}(\mathfrak {h})$ .

If, moreover, H is reductive, we denote by

$$ \begin{align*}\mathfrak{car}_{\mathfrak{h}}=\mathfrak{h}/\!/H:=\mathrm{Spec}(k[\mathfrak{h}]^H) \end{align*} $$

the variety of characteristic polynomials of the elements of $\mathfrak {h}$ , and we have a canonical map $\chi _{\mathfrak {h}}:\mathcal {H}\rightarrow \mathfrak {car}_{\mathfrak {h}}$ .

If H is commutative, then ${\mathcal {H}}\simeq \mathfrak {h}\times \mathrm {B}(H)$ , $\mathfrak {car}_{\mathfrak {h}}\simeq \mathfrak {h}$ and $\chi _{\mathfrak {h}}$ is the first projection.

From now, G is a connected reductive group over k, T is a maximal torus of G, B a Borel subgroup of G containing T, U the unipotent radical of B, N the normalizer $\mathrm {N}_G(T)$ of T in G and W the Weyl group $N/T$ . Through this paper we put

$$ \begin{align*}n:=\mathrm{dim}\, T. \end{align*} $$

We will simply use the notation $\mathfrak {car}$ instead of $\mathfrak {car}_{\mathfrak {g}}$ , and we recall that

$$ \begin{align*}\mathfrak{car}={\mathfrak{t}}/\!/W. \end{align*} $$

We let

$$ \begin{align*}\pi:\mathcal{T}\longrightarrow{\overline{\mathcal{T}}}=[{\mathfrak{t}}/N] \end{align*} $$

be the canonical map.

The character group is denoted by $X^*(T)$ and the cocharacter group by $X_*(T)$ .

When it makes sense, we use freely the subscripts ${\mathrm {reg}}$ and ${\mathrm {rss}}$ for restriction to G-regular or G-regular semisimple elements. Similarly we will use the subscript $\mathrm {nil}$ for restriction to nilpotent elements.

We assume throughout this paper that the characteristic of k is not too small so that ${\mathfrak {t}}_{{\mathrm {reg}}}\neq \emptyset $ and centralizers of semisimple elements of ${\mathfrak {g}}$ are Levi subgroups (of parabolic subgroups) of G (see [Reference Letellier11, §2.6] for an explicit bound on p).

2.7 Lusztig correspondence

Consider the correspondence (which we call Lusztig correspondence)

(2.19)

where the arrows are induced by the inclusion ${\mathfrak {b}}\subset {\mathfrak {g}}$ and by the projection ${\mathfrak {b}}\rightarrow {\mathfrak {t}}$ .

Consider

$$ \begin{align*}X:=\{(x,gB)\in{\mathfrak{g}}\times G/B\,|\, \mathrm{Ad}(g)(x)\in{\mathfrak{b}}\}\\[-9pt] \end{align*} $$

The group G acts on X by $g\cdot (x,hB)=( \mathrm {Ad}(g)(x),ghB)$ , and the map

$$ \begin{align*}B\rightarrow X,\,\, x\mapsto(x,B)\\[-9pt] \end{align*} $$

induces an isomorphism $\mathcal {B}\rightarrow \mathcal {X}:=[X/G]$ .

Under the identification $\mathcal {B}\simeq \mathcal {X}$ , the morphism p is the quotient by G of the Grothendieck-Springer resolution

$$ \begin{align*}\mathrm{pr}_1:X\rightarrow {\mathfrak{g}},\,\, (x,gB)\mapsto x \end{align*} $$

from which we deduce the first assertion of the theorem below.

Theorem 2.18.

  1. (i) The morphism $p:\mathcal {B}\rightarrow \mathcal {G}$ is representable, proper and semi-small.

  2. (ii) We have a factorization of p (Stein factorization)

    where $q'=\chi _{\mathfrak {t}}\circ q:\mathcal {B}\rightarrow \mathcal {T}\rightarrow {\mathfrak {t}}$ , and $(q',p)$ is a small resolution of singularities.

Proof. Above, ${\mathcal {S}}_{{\mathrm {rss}}}:={\mathfrak {t}}\times _{\mathfrak {car}}\mathcal {G}_{{\mathrm {rss}}}$ , $(q',p)$ is an isomorphism, and so $\mathcal {G}_{{\mathrm {rss}}}$ is smooth. The complementary of $\mathcal {G}_{{\mathrm {rss}}}$ in ${\mathcal {S}}$ is of codimension at least $2$ . Therefore, ${\mathcal {S}}$ satisfies the condition $(R_1)$ of Serres’s criterion for normality. Moreover, ${\mathfrak {t}}$ is a complete intersection over $\mathfrak {car}$ , and so by base change, the same is true for ${\mathcal {S}}$ over $\mathcal {G}$ . As $\mathcal {G}$ is smooth, the stack ${\mathcal {S}}$ satisfies the condition $(S_2)$ of Serres’s criterion. Therefore ${\mathcal {S}}$ is normal from which we deduce the proposition.

2.8 Lusztig induction and restriction

The morphism p is representable, proper and q is smooth of pure dimension $0$ . We thus have $p_*=p_!$ and $q^*=q^!$ . The Lusztig induction and restriction functors [Reference Lusztig14, (7.1.7)] are the induction and restriction defined from the correspondence (2.19) with the constant sheaf as a kernel:

$$ \begin{align*}\mathrm{Ind}:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{T})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}),\hspace{.5cm}K\mapsto p_*q^!(K), \end{align*} $$
$$ \begin{align*}\mathrm{Res}:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{T}),\hspace{.5cm}K\mapsto q_!p^*(K). \end{align*} $$

Remark 2.19. Notice that $\mathrm {Res}$ is well-defined as $q_!$ maps bounded complexes to bounded complexes. To see that, we consider the commutative triangle

Since h is an affine fibration, the adjunction morphism

$$ \begin{align*}h_!h^*\rightarrow 1 \end{align*} $$

is an isomorphism, and so we conclude by noticing that a is representable.

By the main result of [Reference Bezrukavnikov and Yom Din3], the functors $\mathrm {Ind}$ and $\mathrm {Res}$ map perverse sheaves to perverse sheaves.

Consider the factorization

(2.20)

where the map $\mathcal {T}\rightarrow \mathfrak {car}$ is either the composition $\mathcal {T}\rightarrow \mathcal {G}\rightarrow \mathfrak {car}$ or the composition $\mathcal {T}\rightarrow {\mathfrak {t}}\rightarrow \mathfrak {car}$ .

By §2.5, we have

$$ \begin{align*} \mathrm{Res}(K)&={\mathrm{pr}_{\mathcal{T}}}_!\left(\mathrm{pr}^*_{\mathcal{G}}(K)\otimes (q,p)_!{\overline{\mathbb{Q}}_{\ell}}\right),\\ \mathrm{Ind}(K)&={\mathrm{pr}_{\mathcal{G}}}_*\,\underline{\mathrm{ Hom}}\left((q,p)_!{\overline{\mathbb{Q}}_{\ell}},\mathrm{pr}_{\mathcal{T}}^!(K)\right)\\ &={\mathrm{pr}_{\mathcal{G}}}_!\left(\mathrm{pr}^*_{\mathcal{T}}(K)\otimes (q,p)_!{\overline{\mathbb{Q}}_{\ell}}\right). \end{align*} $$

The last identity follows from the fact that $q^!=q^*$ and $p_!=p_*$ since we can then regard $\mathrm {Ind}$ as the restriction functor associated to the correspondence $(\mathcal {B},q,p)$ .

Notice also that $(q,p)_!{\overline {\mathbb {Q}}_{\ell }}\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {T}\times _{\mathfrak {car}}\mathcal {G})$ .

2.9 Induction and restriction for perverse sheaves

As we say in the previous section, the two functors $\mathrm {Ind}$ and $\mathrm {Res}$ are t-exact but, as we will see later, the kernel $(q,p)_!{\overline {\mathbb {Q}}_{\ell }}$ is not W-equivariant. In this section we introduce slightly modified functors ${^p}\underline {\mathrm {Ind}}$ and ${^p}\underline {\mathrm {Res}}$ defined from a kernel which is naturally W-equivariant.

We consider the following commutative diagram

(2.21)

where $s:\mathcal {T}\simeq {\mathfrak {t}}\times \mathrm {B}(T)\rightarrow {\mathfrak {t}}$ is the projection on ${\mathfrak {t}}$ . Notice that s is not representable.

Consider the induction functor

$$ \begin{align*}\underline{\mathrm{Ind}}:=\mathrm{Ind}\circ s^![n](n):D_{\mathrm{c}}^+({\mathfrak{t}})\rightarrow D_{\mathrm{c}}^+(\mathcal{G}),\,\,\,\,K\mapsto p_*q'{^!}(K)[n](n). \end{align*} $$

Since the functor $s^![n](n):\mathcal {M}({\mathfrak {t}})\rightarrow \mathcal {M}(\mathcal {T})$ is an equivalence of categories with inverse functor ${^p}{\mathcal {H}}^0\circ \left (s_![-n](-n)\right )$ and since $\mathrm {Ind}$ maps perverse sheaves to perverse sheaves (see §2.8), the functor $\underline {\mathrm {Ind}}$ preserves perversity and we denote by ${^p}\underline {\mathrm {Ind}}$ the induced functor on perverse sheaves:

$$ \begin{align*}{^p}\underline{\mathrm{Ind}}:=\mathrm{Ind}\circ s^![n](n):\mathcal{M}({\mathfrak{t}})\rightarrow\mathcal{M}(\mathcal{G}),\,\,\,\,K\mapsto p_*q'{^!}(K)[n](n). \end{align*} $$

The functor $\underline {\mathrm {Ind}}$ admits a left adjoint

$$ \begin{align*}\underline{\mathrm{Res}}:=s_!\circ\mathrm{Res}[-n](-n):D_{\mathrm{c}}^-(\mathcal{G})\rightarrow D_{\mathrm{c}}^-({\mathfrak{t}}),\,\,\, K\mapsto q^{\prime}_!p^*(K)[-n](-n) \end{align*} $$

which is right t-exact but not left t-exact (unlike $\underline {\mathrm {Ind}}$ ).

Since $\mathrm {Res}$ preserves perversity, for $K\in \mathcal {M}(\mathcal {G})$ , we have

$$ \begin{align*}\underline{\mathrm{Res}}(K)=s_!s^!(K')=K'\otimes R\Gamma_c(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})[-2n](-n) \end{align*} $$

where $K'\in \mathcal {M}({\mathfrak {t}})$ is defined as $s^!(K')[n](n)=\mathrm {Res}(K)$ .

Define the restriction

$$ \begin{align*}{^p}\underline{\mathrm{Res}}:={^p}{\mathcal{H}}^0\circ\underline{\mathrm{Res}}:\mathcal{M}(\mathcal{G})\rightarrow\mathcal{M}({\mathfrak{t}}),\,\,\,K\mapsto K'. \end{align*} $$

Lemma 2.20. ${^p}\underline {\mathrm {Res}}$ is left adjoint to ${^p}\underline {\mathrm {Ind}}$ .

Proof. We have

$$ \begin{align*} \mathrm{Hom}_{\mathcal{M}({\mathfrak{t}})}\left({^p}\underline{\mathrm{Res}}(A),B\right)&=\mathrm{ Hom}_{\mathcal{M}(\mathcal{T})}\left(s^!({^p}\underline{\mathrm{Res}}(A))[n](n),s^!B[n](n)\right)\\ &=\mathrm{Hom}_{\mathcal{M}(\mathcal{T})}\left(\mathrm{Res}(A),s^!B[n](n)\right)\\ &=\mathrm{Hom}_{\mathcal{M}(\mathcal{G})}\left(A,\mathrm{Ind}(s^!B[n](n))\right)\\ &=\mathrm{Hom}_{\mathcal{M}(\mathcal{G})}\left(A,{^p}\underline{\mathrm{Ind}}(B)\right). \\[-36pt] \end{align*} $$

Put

$$ \begin{align*}\overline{{\mathfrak{t}}}:=[{\mathfrak{t}}/W] \end{align*} $$

and let $\pi _{\mathfrak {t}}:{\mathfrak {t}}\rightarrow \overline {{\mathfrak {t}}}$ be the quotient map.

Proposition 2.21. The functors ${{}^p}\underline {\mathrm {Ind}}$ and ${{}^p}\underline {\mathrm {Res}}$ factorize as

$$ \begin{align*}{{}^p}\underline{\mathrm{Ind}}={{}^p}\mathrm{I}\circ\pi_{{\mathfrak{t}}\, *},\hspace{1cm}{{}^p}\underline{\mathrm{Res}}=\pi_{\mathfrak{t}}^*\circ{{}^p}\mathrm{R} \end{align*} $$

where ${{}^p}\mathrm {I}:\mathcal {M}(\overline {{\mathfrak {t}}})\rightarrow \mathcal {M}(\mathcal {G})$ and ${{}^p}\mathrm {R}:\mathcal {M}(\mathcal {G})\rightarrow \mathcal {M}(\overline {{\mathfrak {t}}})$ are defined as

$$ \begin{align*} &{{}^p}\mathrm{I}(K):=\mathrm{pr}_{2\, *}\,\underline{\mathrm{ Hom}}\left({\mathrm{IC}}_{\overline{{\mathfrak{t}}}\times_{\mathfrak{car}}\mathcal{G}},\mathrm{pr}_1^!K\right)[n](n),\\ &{{}^p}\mathrm{R}(K):={{}^p}{\mathcal{H}}^0\left(\mathrm{pr}_{1\, !}\left({\mathrm{IC}}_{\overline{{\mathfrak{t}}}\times_{\mathfrak{car}}\mathcal{G}}\otimes\mathrm{pr}_2^*(K)\right)[-n](-n)\right). \end{align*} $$

Proof. Follows from the diagram (2.21) using that $(q',p)_!{\overline {\mathbb {Q}}_{\ell }}={\mathrm {IC}}_{{\mathfrak {t}}\times _{\mathfrak {car}}\mathcal {G}}$ , which follows from the fact that $(q',p)$ is a small resolution of singularities by Theorem 2.18 (ii).

We have the following proposition.

Proposition 2.22.

  1. (1) Let $K\in \mathcal {M}({\mathfrak {t}})$ be W-equivariant, and let $L\in \mathcal {M}(\mathcal {G})$ . The adjunction isomorphism

    $$ \begin{align*}\mathrm{Hom}_{\mathcal{M}({\mathfrak{t}})}\big({{}^p}\underline{\mathrm{Res}}(L),K\big)\simeq \mathrm{Hom}_{\mathcal{M}(\mathcal{G})}\big(L,{{}^p}\underline{\mathrm{Ind}}(K)\big) \end{align*} $$

    is W-equivariant.

  2. (2) The functor ${{}^p}\mathrm {R}$ is left adjoint to ${{}^p}\mathrm {I}$ .

Proof. From Proposition 2.21 we find that

$$ \begin{align*}{{}^p}\underline{\mathrm{Ind}}(w\cdot f)=w\cdot{{}^p}\underline{\mathrm{Ind}}(f) \end{align*} $$

for any $f\in \mathrm {Hom}({{}^p}\underline {\mathrm {Res}}(L),K)$ and $w\in W$ , from which we deduce the assertion (1). The second assertion is a consequence of (1) together with following identities:

$$ \begin{align*} &\mathrm{Hom}_{\mathcal{M}(\overline{{\mathfrak{t}}})}\left({{}^p}\mathrm{R}(L),\overline{K}\right)=\mathrm{ Hom}_{\mathcal{M}({\mathfrak{t}})}\left({{}^p}\underline{\mathrm{Res}}(L),K\right)^W,\\ &\mathrm{Hom}_{\mathcal{M}(\mathcal{G})}\left(L,{{}^p}\mathrm{I}(\overline{K})\right)=\mathrm{ Hom}_{\mathcal{M}(\mathcal{G})}\left(L,{{}^p}\underline{\mathrm{Ind}}(K)\right)^W \end{align*} $$

where $K=\pi _{\mathfrak {t}}^*(\overline {K})$ .

2.10 Springer action

From Borho-MacPherson construction of the Springer action [Reference Borho and MacPherson4], the complex $p_!{\overline {\mathbb {Q}}_{\ell }}$ is endowed with an action of the Weyl group W (i.e., a group homomorphism $W\rightarrow \mathrm {Aut}(p_!({\overline {\mathbb {Q}}_{\ell }}))$ ). Their strategy was to prove that $p_*{\overline {\mathbb {Q}}_{\ell }}$ is the intermediate extension of some smooth $\ell $ -adic sheaf on $\mathcal {G}_{\mathrm {rss}}$ on which W acts. From the diagram (2.21), we see that $p_!{\overline {\mathbb {Q}}_{\ell }}=\mathrm {pr}_{2\, !}{\mathrm {IC}}_{{\mathfrak {t}}\times _{\mathfrak {car}}\mathcal {G}}$ , and so the action of W follows from the fact that ${\mathrm {IC}}_{{\mathfrak {t}}\times _{\mathfrak {car}}\mathcal {G}}$ is naturally W-equivariant.

This defines an action of W on $H^i(\mathcal {B},{\overline {\mathbb {Q}}_{\ell }})$ as well as an action on the cohomology of the fibres. These actions are compatible with the restriction maps from the cohomology of $\mathcal {B}$ to the cohomology of the fibres.

On the other hand, the natural map $\mathrm {B}(T)\rightarrow \mathrm {B}(B)$ is a U-fibration, and so $H^i(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})=H^i(\mathrm {B}(B),{\overline {\mathbb {Q}}_{\ell }})$ . The action of W on $\mathrm {B}(T)$ induces thus an action of W on $H^i(\mathrm {B}(B),{\overline {\mathbb {Q}}_{\ell }})$ . This action coincides with the Springer action (regarding $\mathrm {B}(B)$ as the zero fibre of p).

Lemma 2.23. The restriction map $H^i(\mathrm {B}(B),{\overline {\mathbb {Q}}_{\ell }})\rightarrow H^i(\mathcal {B},{\overline {\mathbb {Q}}_{\ell }})$ induced by the map $\mathcal {B}\rightarrow \mathrm {B}(B)$ (given by the B-torsor ${\mathfrak {b}}\rightarrow \mathcal {B}$ ) is W-equivariant for the Springer actions.

Proof. We know that the restriction map

$$ \begin{align*}i^*:H^i(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}})\rightarrow H^i(\mathrm{B}(B),{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

of the inclusion $i:\mathrm {B}(B)\hookrightarrow \mathcal {B}$ is W-equivariant for the Springer actions.

The morphism $b:\mathcal {B}\rightarrow \mathrm {B}(B)$ is a vector bundle with fibre ${\mathfrak {b}}$ . Hence $b^*$ is an isomorphism with inverse $i^*$ and so is W-equivariant.

3 Steinberg stacks

3.1 Geometry of Steinberg stacks

We consider the following stacks

$$ \begin{align*}\mathcal{Z}:=\mathcal{B}\times_{\mathcal{G}}\mathcal{B},\hspace{1cm}{\mathcal{Y}}:=\mathcal{B}\times_{\mathcal{S}}\mathcal{B}. \end{align*} $$

We have the following cartesian diagrams

where the top horizontal arrow is the natural map, and the last two arrows are the diagonal morphisms. Since the diagonal morphism ${\mathfrak {t}}\rightarrow {\mathfrak {t}}\times _{\mathfrak {car}}{\mathfrak {t}}$ is closed, the stack ${\mathcal {Y}}$ is a closed substack of $\mathcal {Z}$ .

Remark 3.1. Consider

$$ \begin{align*}Z=\{(x,gB,g'B)\in {\mathfrak{g}}\times G/B\times G/B\,|\, \mathrm{Ad}(g^{-1})(x)\in {\mathfrak{b}},\, \mathrm{Ad}({g'}^{-1})(x)\in {\mathfrak{b}}\} \end{align*} $$

so that $\mathcal {Z}=[Z/G]$ where G acts on Z by

$$ \begin{align*}(x,gB,g'B)\cdot h=(\mathrm{Ad}(h^{-1})x,h^{-1}gB,h^{-1}g'B). \end{align*} $$

The canonical morphisms $\mathcal {B}\rightarrow \mathrm {B}(B)$ and $\mathcal {G}\rightarrow \mathrm {B}(G)$ induce a morphism

and the canonical map $[B\backslash G/B]\rightarrow \mathrm {B}(B)\times _{\mathrm {B}(G)}\mathrm {B}(B)$ is an isomorphism.

Consider the stratification

$$ \begin{align*}[B\backslash G/B]=\coprod_{w\in W}\mathcal{O}_w, \end{align*} $$

where $\mathcal {O}_w=[B\backslash BwB/B]$ . Notice that the natural map $\mathrm {B}(B_w)\rightarrow \mathcal {O}_w$ is an isomorphism.

This induces partitions into locally closed substacks

$$ \begin{align*}\mathcal{Z}=\coprod_{w\in W}\mathcal{Z}_w,\hspace{1cm}{\mathcal{Y}}=\coprod_{w\in W}{\mathcal{Y}}_w. \end{align*} $$

For $w\in W$ , put

$$ \begin{align*}B_w:=B\cap wBw^{-1},\hspace{.5cm}{\mathfrak{b}}_w:=\mathrm{Lie}(B_w),\hspace{.5cm}U_w:=U\cap wUw^{-1}, \hspace{.5cm}{\mathfrak{u}}_w:=\mathrm{Lie}(U_w). \end{align*} $$

Then

$$ \begin{align*}\mathcal{Z}_w=[{\mathfrak{b}}_w/B_w],\hspace{1cm}{\mathcal{Y}}_w=[({\mathfrak{t}}^w+{\mathfrak{u}}_w)/B_w] \end{align*} $$

where $B_w$ acts by the adjoint action and ${\mathfrak {t}}^w$ are the points of ${\mathfrak {t}}$ fixed by w.

Since $B_w=TU_w$ , we proved the following proposition.

Proposition 3.2.

  1. (1) For all $w\in W$ , the projection

    $$ \begin{align*}\mathcal{Z}_w\rightarrow\mathcal{T} \end{align*} $$

    induced by the canonical projection ${\mathfrak {b}}\rightarrow {\mathfrak {t}}$ is a fibration with fibre isomorphic to $ [{\mathfrak {u}}_w/U_w]$ , where $U_w$ acts by the adjoint action.

  2. (2) The fibres of the projection $\mathcal {Z}_w\rightarrow \mathcal {O}_w$ (resp. ${\mathcal {Y}}_w\rightarrow \mathcal {O}_w$ ) are affine spaces all of same dimension ${\mathfrak {b}}_w$ (resp. $\mathrm {dim}\,{\mathfrak {t}}^w+\mathrm {dim}\,{\mathfrak {u}}_w$ ).

3.2 Purity of cohomology

Proposition 3.3. The compactly supported cohomology of $\mathcal {Z}$ and ${\mathcal {Y}}$ is pure and vanishes in odd degree.

Proof. We prove it for ${\mathcal {Y}}$ , but the proof is completely similar for $\mathcal {Z}$ . Let us choose $k_o$ , a finite subfield of k such that G, B and T are defined over $k_o$ and T is split. Then $\mathrm {Gal}(k/k_o)$ acts trivially on W.

Recall (see §3) that we have a partition into locally closed substacks

(3.1) $$ \begin{align} {\mathcal{Y}}=\coprod_{w\in W}{\mathcal{Y}}_w. \end{align} $$

By our choice of $k_o$ , each stratum is defined over $k_o$ .

We choose a total order $\{w_0,w_1,\dots \}$ on W so that we have a decreasing filtration of closed substacks

$$ \begin{align*}{\mathcal{Y}}={\mathcal{Y}}_0\supset{\mathcal{Y}}_1\supset\cdots\supset{\mathcal{Y}}_{|W|-1}\supset\mathcal{Z}_{|W|}=\emptyset \end{align*} $$

satisfying ${\mathcal {Y}}_i\backslash {\mathcal {Y}}_{i+1}={\mathcal {Y}}_{w_i}$ for all i. This defines a spectral sequence [Reference Deligne5, Chapter 6, Formula (2.5.2)] from which we can reduce the proof of the purity of the cohomology of ${\mathcal {Y}}$ and the vanishing in odd degrees to the analogous statement for ${\mathcal {Y}}_w$ .

The fibres of the projection ${\mathcal {Y}}_w\rightarrow \mathcal {O}_w$ are affine spaces all of same dimension $n(w)=\mathrm {dim}\,{\mathfrak {t}}^w+\mathrm {dim}\,{\mathfrak {u}}_w$ by Proposition 3, and so

$$ \begin{align*}H_c^i({\mathcal{Y}}_w,{\overline{\mathbb{Q}}_{\ell}})=H_c^{i-2n(w)}(\mathcal{O}_w,{\overline{\mathbb{Q}}_{\ell}})(-n(w)). \end{align*} $$

Recall also that the map $\mathrm {B}(B_w)\rightarrow \mathcal {O}_w$ is an isomorphism and that

$$ \begin{align*}H_c^{k+2\mathrm{dim}\, U_w}(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})(\mathrm{dim}\, U_w)=H_c^k(\mathrm{B}(B_w),{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

Therefore,

$$ \begin{align*}H_c^i({\mathcal{Y}}_w,{\overline{\mathbb{Q}}_{\ell}})=H_c^{i-2\mathrm{dim}\,{\mathfrak{t}}^w}(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})(-\mathrm{dim}\,{\mathfrak{t}}^w). \end{align*} $$

Since the cohomology of $\mathrm {B}(T)$ is pure and vanishes in odd degree, the same is true for $H_c^i({\mathcal {Y}}_w,{\overline {\mathbb {Q}}_{\ell }})$ .

3.3 Restriction to the diagonal

Notice that

$$ \begin{align*}H_c^i(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}})=H_c^i(\mathcal{G},p_!{\overline{\mathbb{Q}}_{\ell}}\otimes p_!{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

and so $H_c^i(\mathcal {Z},{\overline {\mathbb {Q}}_{\ell }})$ is naturally equipped with an action of $W\times W$ .

The aim of this section is to prove the following theorem.

Theorem 3.4. The cohomological restriction

$$ \begin{align*}H_c^{2i}(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}})\longrightarrow H_c^{2i}(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

of the diagonal morphism $\mathcal {B}\rightarrow \mathcal {Z}$ is W-equivariant for the Springer actions (where we consider the diagonal action of W on the source).

Let $q':\mathcal {B}\rightarrow {\mathfrak {t}}$ be induced by the canonical projection ${\mathfrak {b}}\rightarrow {\mathfrak {t}}$ . Then

$$ \begin{align*}H^i_c(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}})=H_c^i({\mathfrak{t}}\times_{\mathfrak{car}}{\mathfrak{t}},(q',q')_!{\overline{\mathbb{Q}}_{\ell}}),\hspace{1cm}H_c^i(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}})=H_c^i({\mathfrak{t}},q^{\prime}_!{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

Choose a total ordering $\{w_0,w_1,\dots \}$ on W so that we have a decreasing filtration of closed substacks

$$ \begin{align*}\mathcal{Z}=\mathcal{Z}_0\supset\mathcal{Z}_1\supset\cdots\supset\mathcal{Z}_{|W|-1}\supset\mathcal{Z}_{|W|}=\emptyset \end{align*} $$

satisfying $\mathcal {Z}_i\backslash \mathcal {Z}_{i+1}=\mathcal {Z}_{w_i}$ for all i.

By [Reference Deligne5, Chapter 6, Formula (2.5.2)], we have a spectral sequence

$$ \begin{align*}E_1^{ij}={\mathcal{H}}^{i+j} \left(\left((q',q')|_{\mathcal{Z}_{w_i}}\right)_!{\overline{\mathbb{Q}}_{\ell}}\right)\Rightarrow {\mathcal{H}}^{i+j}(q',q')_!{\overline{\mathbb{Q}}_{\ell}}. \end{align*} $$

For $w\in W$ , consider the morphism

$$ \begin{align*}\Delta_{{\mathfrak{t}},w}:{\mathfrak{t}}\longrightarrow {\mathfrak{t}}\times_{\mathfrak{car}}{\mathfrak{t}},\hspace{1cm}t\mapsto (w(t),t) \end{align*} $$

and the following commutative diagram:

Then

$$ \begin{align*}((q',q')|_{\mathcal{Z}_w})_!{\overline{\mathbb{Q}}_{\ell}}=\Delta_{{{\mathfrak{t}},w}\,*}q^{\prime}_{w\,*}{\overline{\mathbb{Q}}_{\ell}}=\Delta_{{\mathfrak{t}},w\,*}{\overline{\mathbb{Q}}_{\ell}}\otimes R\Gamma_c(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

As $H^{\mathrm {odd}}_c(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})$ vanishes, the spectral sequence degenerates at $E_1$ .

Proof of Theorem 3.4.

Since the above spectral sequence degenerates at $E_1$ , we have ${\mathcal {H}}_c^{\mathrm {odd}}(q',q')_!{\overline {\mathbb {Q}}_{\ell }}=0$ , and ${\mathcal {H}}^{\mathrm {even}}(q',q')_!{\overline {\mathbb {Q}}_{\ell }}$ is a successive extension of the $\Delta _{{\mathfrak {t}},w\,*}{\overline {\mathbb {Q}}_{\ell }}\otimes H^{\mathrm { even}}_c(\mathrm {B}(T),{\overline {\mathbb {Q}}_{\ell }})$ . By Proposition 2.8, ${\mathcal {H}}^{2i}(q',q')_!{\overline {\mathbb {Q}}_{\ell }}$ is thus a perverse sheaf (up to a shift) that is the intermediate extension of its restriction to ${\mathfrak {t}}_{\mathrm {reg}}\times _{\mathfrak {car}}{\mathfrak {t}}_{\mathrm {reg}}$ .

We thus have

$$ \begin{align*}{\mathcal{H}}^{2i}(q',q')_!{\overline{\mathbb{Q}}_{\ell}}=\Delta_*{\overline{\mathbb{Q}}_{\ell}}\otimes H^{2i}_c(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

where $\Delta :W\times {\mathfrak {t}}\rightarrow {\mathfrak {t}}\times _{\mathfrak {car}}{\mathfrak {t}}$ , $(w,t)\mapsto (w(t),t)$ is the normalization morphism.

Using the spectral sequence

$$ \begin{align*}H_c^i\left({\mathfrak{t}}\times_{\mathfrak{car}}{\mathfrak{t}},{\mathcal{H}}^j(q',q')_!{\overline{\mathbb{Q}}_{\ell}}\right)\Rightarrow H_c^{i+j}(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

together with the fact that $H_c^i({\mathfrak {t}}\times _{\mathfrak {car}}{\mathfrak {t}},\Delta _*{\overline {\mathbb {Q}}_{\ell }})=0$ unless $i=2n$ , we deduce that

$$ \begin{align*}H_c^{-2i}(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}})=H_c^{2n}({\mathfrak{t}}\times_{\mathfrak{car}}{\mathfrak{t}},\Delta_*{\overline{\mathbb{Q}}_{\ell}})\otimes H_c^{-2n-2i}(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

The restriction morphism $H_c^i(\mathcal {Z},{\overline {\mathbb {Q}}_{\ell }})\rightarrow H_c^i(\mathcal {B},{\overline {\mathbb {Q}}_{\ell }})$ is induced by the restriction morphism

$$ \begin{align*}\Delta_{{\mathfrak{t}},1}^*:H_c^{2n}({\mathfrak{t}}\times_{\mathfrak{car}}{\mathfrak{t}},\Delta_*{\overline{\mathbb{Q}}_{\ell}})\rightarrow H_c^{2n}({\mathfrak{t}},{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

which is W-equivariant, hence the theorem.

4 Postnikov diagrams of kernels

The aim of this section is to compute the kernel

$$ \begin{align*}{\mathcal{N}}:=(q,p)_!{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

as well as its restriction to nilpotent elements.

To alleviate the notation, we will denote by f the representable morphism

$$ \begin{align*}(q',p):\mathcal{B}\rightarrow{\mathcal{S}} \end{align*} $$

considered in Theorem 2.18.

The map $(q,p)$ decomposes as

(4.1)

or equivalently as

under the identification $\mathcal {T}={\mathfrak {t}}\times \mathrm {B}(T)$ . Notice that $\tau $ corresponds to the T-torsor $\dot {\mathcal {B}}=[{\mathfrak {b}}/U]\rightarrow [{\mathfrak {b}}/B]=\mathcal {B}$ .

The first map is a T-torsor which fits into the cartesian diagram

where the map $\mathrm {B}(T)\rightarrow \mathrm {B}(T)\times \mathrm {B}(T)$ is the diagonal embbeding, and $\mathrm {B}(T)\times \mathrm {B}(T)\rightarrow \mathrm {B}(T)$ is induced by $T\times T\rightarrow T, (t,h)\mapsto th^{-1}$ .

4.1 Postnikov diagrams associated to T-torsors

Let ${\mathcal {V}}$ be an algebraic stack and $\dot {{\mathcal {V}}}$ a T-torsor $\rho :\dot {{\mathcal {V}}}\rightarrow {\mathcal {V}}$ . We want to compute $\rho _!{\overline {\mathbb {Q}}_{\ell }}$ .

This torsor corresponds to a morphism

$$ \begin{align*}\sigma:{\mathcal{V}}\rightarrow\mathrm{B}(T). \end{align*} $$

We have a Chern class morphism

$$ \begin{align*}c_{\mathrm{can}}:X^*(T)\rightarrow H^2(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})(1) \end{align*} $$

associated to the canonical T-torsor $\mathrm {Spec}(k)\rightarrow \mathrm {B}(T)$ , which induces an isomorphism

$$ \begin{align*}X^*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}\simeq H^2(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})(1). \end{align*} $$

Composed with $\sigma ^*$ , it induces a Chern class morphism

$$ \begin{align*}c_{\rho}:X^*(T)\rightarrow H^2({\mathcal{V}},{\overline{\mathbb{Q}}_{\ell}})(1). \end{align*} $$

Concretely, if $\chi \in X^*(T)$ , then $c_{\rho }(\chi )$ is the Chern class of the line bundle

$$ \begin{align*}(\dot{{\mathcal{V}}}\times\mathbb{A}^1)/T\rightarrow{\mathcal{V}}, \end{align*} $$

where T acts on $\mathbb {A}^1$ as $x\cdot t=\chi (t^{-1})x$ , for $(x,t)\in \mathbb {A}^1\times T$ .

Since $H^2({\mathcal {V}},{\overline {\mathbb {Q}}_{\ell }})={\mathrm {Ext}}^2_{\mathcal {V}}({\overline {\mathbb {Q}}_{\ell }},{\overline {\mathbb {Q}}_{\ell }})=\mathrm {Hom}_{\mathcal {V}}({\overline {\mathbb {Q}}_{\ell }},{\overline {\mathbb {Q}}_{\ell }}[2])$ , we can regard c as a map

$$ \begin{align*}c_{\rho}:{\overline{\mathbb{Q}}_{\ell}}\rightarrow X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[2](1) \end{align*} $$

in $D_{\mathrm {c}}^{\mathrm {b}}({\mathcal {V}})$ .

This defines a complex of objects of $D_{\mathrm {c}}^{\mathrm {b}}({\mathcal {V}})$

$$ \begin{align*}{\overline{\mathbb{Q}}_{\ell}}[-2n](-n)\overset{\partial_n}{\longrightarrow} X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[2-2n](1-n)\overset{\partial_{n-1}}{\longrightarrow}\bigwedge^2X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[4-2n](2-n)\overset{\partial_{n-2}}{\longrightarrow}\cdots \end{align*} $$
(4.2) $$ \begin{align} \cdots\rightarrow\bigwedge^{n-1}X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[-2](-1)\overset{\partial_1}{\longrightarrow}\bigwedge^nX_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}, \end{align} $$

where $\partial _{n-i+1}[2n-2i+2](n-i+1)$ is induced by the morphism

$$ \begin{align*}\bigwedge^{i-1}X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}\longrightarrow\bigwedge^iX_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[2](1) \end{align*} $$

that maps v to $v\wedge c_{\rho }(1)$ .

Proposition 4.1.

  1. (1) We have

    $$ \begin{align*}{{}^p}{\mathcal{H}}^i(\rho_!{\overline{\mathbb{Q}}_{\ell}})={\mathcal{H}}^i(\rho_!{\overline{\mathbb{Q}}_{\ell}})\simeq\bigwedge^{2n-i}X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}(n-i). \end{align*} $$
  2. (2) The complex (4.2) is the base $\Lambda _b(\rho _!{\overline {\mathbb {Q}}_{\ell }})$ of the Postnikov diagram $\Lambda (\rho _!{\overline {\mathbb {Q}}_{\ell }})$ .

Proof. The proposition reduces to the case $n=1$ using an isomorphism $T\simeq (\mathbb {G}_m)^n$ . Indeed, the complex (4.2) can be realized as the tensor product of analogous complexes associated to rank $1$ tori.

4.2 Postnikov diagram of ${\mathcal {N}}$

Since the map $\hat {f}:\hat {\mathcal {B}}\rightarrow \hat {{\mathcal {S}}}$ is a small resolution of singularities, we have

$$ \begin{align*}\hat{f}_!{\overline{\mathbb{Q}}_{\ell}}={\mathrm{IC}}_{\hat{{\mathcal{S}}}}. \end{align*} $$

Following §4.1 we now regard the Chern class morphism

$$ \begin{align*}c_{\delta}:X^*(T)\rightarrow H^2(\hat{\mathcal{B}},{\overline{\mathbb{Q}}_{\ell}})(1) \end{align*} $$

associated to the T-torsor $\delta :\mathcal {B}\rightarrow \hat {\mathcal {B}}$ as a morphism

$$ \begin{align*}c_{\delta}:{\overline{\mathbb{Q}}_{\ell}}\rightarrow X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[2](1). \end{align*} $$

Applying $\hat {f}_!$ we get

$$ \begin{align*}\hat{f}_!(c_{\delta}):{\mathrm{IC}}_{\hat{{\mathcal{S}}}}\rightarrow X_*(T)\otimes{\mathrm{IC}}_{\hat{{\mathcal{S}}}}[2](1). \end{align*} $$

Applying the functor $\hat {f}_!$ to the complex $\Lambda _b(\delta _!{\overline {\mathbb {Q}}_{\ell }})$ we obtain a complex

(4.3) $$ \begin{align} &{\mathrm{IC}}_{\hat{{\mathcal{S}}}}[-2n](-n)\overset{\partial_n}{\longrightarrow} X_*(T)\otimes{\mathrm{IC}}_{\hat{{\mathcal{S}}}}[2-2n](1-n)\overset{\partial_{n-1}}{\longrightarrow}\cdots \end{align} $$
$$\begin{align*} &\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\quad \cdots \overset{\partial_1}{\longrightarrow}\left(\bigwedge^{n}X_*(T)\right)\otimes{\mathrm{IC}}_{\hat{{\mathcal{S}}}}, \notag \end{align*}$$

where $\partial _{n-i+1}[2n-2i+2](n-i+1)$ is induced by the morphism

$$ \begin{align*}\left(\bigwedge^{i-1}X_*(T)\right)\otimes{\mathrm{IC}}_{\hat{{\mathcal{S}}}}\longrightarrow\left(\bigwedge^iX_*(T)\right)\otimes{\mathrm{IC}}_{\hat{{\mathcal{S}}}}[2](1) \end{align*} $$

given by $v\otimes s\mapsto v\wedge f_!(c_{\delta })(s)$ .

Proposition 4.2.

  1. (1) The perverse cohomology sheaves of ${\mathcal {N}}$ are

    $$ \begin{align*}{^{\mathrm{p}}}{\mathcal{H}}^i\left({\mathcal{N}}\right) =\left(\bigwedge^{2n-i}X_*(T)\right)\otimes{\mathrm{IC}}_{\hat{{\mathcal{S}}}}(n-i). \end{align*} $$
  2. (2) We have $\Lambda ({\mathcal {N}})=\hat {f}_!\left (\Lambda (\delta _!{\overline {\mathbb {Q}}_{\ell }})\right )$ .

  3. (3) Assume that G, B and T are defined over a finite subfield $k_o$ of k. The diagram $\Lambda ({\mathcal {N}})$ is the unique Postnikov diagram defined over $k_o$ whose base is the complex (4.3).

Proof. The assertion (1) follows from the fact that the morphism $\hat {f}$ is small and that the cohomology groups of $\Lambda (\delta _!{\overline {\mathbb {Q}}_{\ell }})$ are constant (see Proposition 4.1(1)). The assertion (2) follows from Lemma 2.3.

To prove assertion (3), we choose a finite subfield $k_o$ of k on which G, T and B are defined, and we let $T_o$ and $\hat {{\mathcal {S}}}_o$ be the induced $k_o$ -structure on T and $\hat {{\mathcal {S}}}$ . We want to prove that $\hat {f}_{o!}\left (\Lambda (\delta _{o!}{\overline {\mathbb {Q}}_{\ell }})\right )$ is the unique Postnikov diagram that completes the complex (4.3) with T and $\hat {{\mathcal {S}}}$ replaced by $T_o$ and $\hat {{\mathcal {S}}}_o$ .

We need to prove that the hypothesis of Lemma 2.5 is satisfied. The condition (2.5) is verified as

$$ \begin{align*}\mathrm{Hom}({\mathrm{IC}}_{\hat{{\mathcal{S}}}_o}[-2j](-j),{\mathrm{IC}}_{\hat{{\mathcal{S}}}_o}[-2i](-i))=\mathrm{Ext}^{2(j-i)}({\mathrm{IC}}_{\hat{{\mathcal{S}}}_o},{\mathrm{IC}}_{\hat{{\mathcal{S}}}_o}(j-i))=0 \end{align*} $$

for all $j<i$ .

The proof of the condition (2.6) reduces to prove that

$$ \begin{align*}\mathrm{Hom}({\mathrm{IC}}_{\hat{{\mathcal{S}}}_o}[-2j](-j),{\mathrm{IC}}_{\hat{{\mathcal{S}}}_o}[-2i-k](-i))=\mathrm{Ext}^{2(j-i)-k}({\mathrm{IC}}_{\hat{{\mathcal{S}}}_o},{\mathrm{IC}}_{\hat{{\mathcal{S}}}_o}(j-i))=0 \end{align*} $$

for all $j>i$ and $k\geq 1$ . But this is clear from the next proposition using the exact sequence (2.8).

Proposition 4.3. $\mathrm {Ext}^j_{\hat {{\mathcal {S}}}}({\mathrm {IC}}_{\hat {{\mathcal {S}}}},{\mathrm {IC}}_{\hat {{\mathcal {S}}}})=0$ if j is odd and $\mathrm {Ext}^{2i}_{\hat {{\mathcal {S}}}}({\mathrm {IC}}_{\hat {{\mathcal {S}}}},{\mathrm {IC}}_{\hat {{\mathcal {S}}}})$ is pure of weight $2i$ .

Proof. We need to compute

$$ \begin{align*}\mathrm{Ext}^i_{\hat{{\mathcal{S}}}}({\mathrm{IC}}_{\hat{{\mathcal{S}}}},{\mathrm{IC}}_{\hat{{\mathcal{S}}}})=\mathrm{Hom}({\mathrm{IC}}_{\hat{{\mathcal{S}}}},{\mathrm{IC}}_{\hat{{\mathcal{S}}}}[i]). \end{align*} $$

Since $\hat {{\mathcal {S}}}=\mathrm {B}(T)\times {\mathcal {S}}$ and since the statement of the proposition is true if we replace $\hat {S}$ by $\mathrm {B}(T)$ (noticing that ${\mathrm {IC}}_{\mathrm {B}(T)}={\overline {\mathbb {Q}}_{\ell }}$ ), by Künneth formula we are reduced to prove the proposition with ${\mathcal {S}}$ instead of $\hat {{\mathcal {S}}}$ .

Consider the cartesian diagram

Since f is representable, the morphism $\mathrm {pr}_1$ is also representable. We have

$$ \begin{align*} \mathrm{Hom}({\mathrm{IC}}_{\mathcal{S}},{\mathrm{IC}}_{\mathcal{S}}[i])&=\mathrm{Hom}(f_!{\overline{\mathbb{Q}}_{\ell}},f_!{\overline{\mathbb{Q}}_{\ell}}[i])\\ &=\mathrm{Hom}(f^*f_!{\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}}[i])\\ &=\mathrm{Hom}(\mathrm{pr}_{1!}{\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}}[i])\\ &=\mathrm{Hom}({\overline{\mathbb{Q}}_{\ell}},\mathrm{pr}_1^!{\overline{\mathbb{Q}}_{\ell}}[i])\\ &=H^i({\mathcal{Y}},\mathrm{pr}_1^!{\overline{\mathbb{Q}}_{\ell}})\\ &=H_c^{-i}({\mathcal{Y}},{\overline{\mathbb{Q}}_{\ell}}), \end{align*} $$

where the last identity is by Poincaré duality (notice that $\mathrm {dim}\,{\mathcal {Y}}=0$ ). We thus conclude from Proposition 3.3.

4.3 Restriction to nilpotent elements

We let $\mathfrak {z}$ be a locally closed subset of $z(\mathfrak {g})$ . We consider the Lusztig correspondence

over $\mathfrak {z}=\mathfrak {z}/\!/W\subset \mathfrak {car}$ .

The T-torsor $\delta _{\mathfrak {z}}:\mathcal {B}_{\mathfrak {z}}\rightarrow \hat {\mathcal {B}}_{\mathfrak {z}}=\mathrm {B}(T)\times \mathcal {B}_{\mathfrak {z}}$ induced from $\delta $ gives rise to a Chern class morphism

$$ \begin{align*}c_{\delta_{\mathfrak{z}}}:{\overline{\mathbb{Q}}_{\ell}}\rightarrow X_*(T)\otimes{\overline{\mathbb{Q}}_{\ell}}[2](1) \end{align*} $$

and so following the same lines as in §4.2, we end up with a complex

(4.4) $$ \begin{align} &\left(\overline{\mathbb{Q}}_{\ell,\,\mathrm{B}(T)}\boxtimes p_{\mathfrak{z}\,!}{\overline{\mathbb{Q}}_{\ell}}\right)[-2n](-n)\rightarrow X_*(T)\otimes \left(\overline{\mathbb{Q}}_{\ell,\,\mathrm{B}(T)}\boxtimes p_{\mathfrak{z}\,!}{\overline{\mathbb{Q}}_{\ell}}\right)[2-2n](1-n)\rightarrow\cdots \end{align} $$
$$\begin{align*} &\ \qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad \cdots\longrightarrow\left(\bigwedge^nX_*(T)\right)\otimes \left(\overline{\mathbb{Q}}_{\ell,\,\mathrm{B}(T)}\boxtimes p_{\mathfrak{z}\,!}{\overline{\mathbb{Q}}_{\ell}}\right).\notag \end{align*}$$

which is the restriction of the complex (4.3) to $\hat {{\mathcal {S}}}_{\mathfrak {z}}$ .

If $\mathfrak {z}=0$ , we will replace the subscript $\mathfrak {z}$ by nil.

Let $\mathrm {pr}_{\mathrm {nil}}:\hat {{\mathcal {S}}}_{\mathfrak {z}}\rightarrow \hat {{\mathcal {S}}}_{\mathrm { nil}}=\mathrm {B}(T)\times \mathcal {G}_{\mathrm {nil}}$ be the morphism induced by the projection $\mathfrak {z}+{\mathfrak {g}}_{\mathrm {nil}}\rightarrow {\mathfrak {g}}_{\mathrm {nil}}$ .

Proposition 4.4.

  1. (1) We have

    $$ \begin{align*}(q_{\mathfrak{z}},p_{\mathfrak{z}})_!{\overline{\mathbb{Q}}_{\ell}}=\mathrm{pr}_{\mathrm{nil}}^*\left((q_{\mathrm{nil}},p_{\mathrm{nil}})_!{\overline{\mathbb{Q}}_{\ell}}\right). \end{align*} $$
  2. (2) Assume also that $G, B$ and T are defined over a finite subfield $k_o$ of k. The Postnikov diagram $\Lambda ((q_{\mathrm {nil}},p_{\mathrm {nil}})_!{\overline {\mathbb {Q}}_{\ell }})=\hat {f}_{\mathrm {nil}\, !}\big (\Lambda (\delta _{\mathrm {nil}\, !}{\overline {\mathbb {Q}}_{\ell }})\big )$ is the unique Postnikov diagram defined over $k_o$ whose base is the complex (4.4) with $\mathfrak {z}=0$ .

Proof. The assertion (1) is clear. The proof of assertion (2) goes exactly along the same lines as the proof of Proposition 4.2.

5 Descent

As explained in §5.4, the kernel ${\mathcal {N}}$ does not descend to ${\overline {\mathcal {T}}}\times _{\mathfrak {car}}\mathcal {G}$ . However, we will prove in this section that we have a descent result if we restrict ourselves to strata of $\mathfrak {car}$ that we are now defining.

5.1 The main theorem

We have a natural stratification of $\mathfrak {car}$ into smooth locally closed subsets indexed by the set $\mathfrak {L}$ of G-conjugacy classes of Levi subgroups (of parabolic subgroups) of G

$$ \begin{align*}\mathfrak{car}=\coprod_{\lambda\in\mathfrak{L}}\mathfrak{car}_{\lambda}. \end{align*} $$

Concretely, let L be a representative of $\lambda \in \mathfrak {L}$ containing T. Then $\mathfrak {car}_{\lambda }$ is the image of

$$ \begin{align*}z(\mathfrak{l})^o:=\{x\in \mathfrak{l}\,|\,C_G(x)=L\}\subset z(\mathfrak{l})\subset {\mathfrak{t}} \end{align*} $$

by the quotient map ${\mathfrak {t}}\rightarrow \mathfrak {car}$ .

If $\mathcal {X}$ is either $\mathcal {T},\mathcal {B},\hat {\mathcal {B}}, {\mathcal {S}}, \hat {{\mathcal {S}}}, {\overline {\mathcal {T}}} $ or $\mathcal {G}$ we put

$$ \begin{align*}\mathcal{X}_{\lambda}:=\mathcal{X}\times_{\mathfrak{car}}\mathfrak{car}_{\lambda} \end{align*} $$

for any $\lambda \in \mathfrak {L}$ .

We consider the Lusztig correspondence over $\lambda \in \mathfrak {L}$

Notice that $\mathcal {T}_{\lambda }=[{\mathfrak {t}}_{\lambda }/T]\simeq {\mathfrak {t}}_{\lambda }\times \mathrm {B}(T)$ with

$$ \begin{align*}{\mathfrak{t}}_{\lambda}=\coprod_{g\in N_G(T)/N_G(L,T)}g\,z(\mathfrak{l})^og^{-1}. \end{align*} $$

Notice that if for some $g\in G$ and $s\in z(\mathfrak {l})^o$ we have $\mathrm {Ad}(g)(s)\in z(\mathfrak {l})^o$ , then $g\in N_G(L)$ [Reference Letellier11, Lemma 2.6.16].

We thus have isomorphisms of stacks

$$ \begin{align*}\mathcal{G}_{\lambda}\simeq [(z(\mathfrak{l})^o+\mathfrak{l}_{\mathrm{nil}})/N_G(L)],\hspace{1cm}\overline{\mathcal{T}}_{\lambda}=[{\mathfrak{t}}_{\lambda}/N]\simeq [z(\mathfrak{l})^o/N_G(L,T)]. \end{align*} $$

Put $B^L:=B\cap L$ , and let ${\mathfrak {u}}^L$ be the Lie algebra of the unipotent radical of $B^L$ . We consider the following commutative diagram (as in §4.3 with $G=L$ and $\mathfrak {z}=z(\mathfrak {l})^o$ ):

(5.1)

Put

$$ \begin{align*}W^L:=N_L(T)/T,\hspace{1cm}\widehat{W}^L:=N_G(L,T)/T,\hspace{1cm}W_L:=N_G(L)/L \end{align*} $$

We have an exact sequence

$$ \begin{align*}1\rightarrow W^L\rightarrow \widehat{W}^L\rightarrow W_L\rightarrow 1 \end{align*} $$

and the group $\widehat {W}^L$ acts on

$$ \begin{align*}[z(\mathfrak{l})^o/T]\times_{z(\mathfrak{l})^o} [(z(\mathfrak{l})^o+\mathfrak{l}_{\mathrm{nil}})/L] \end{align*} $$

in the natural way on the first factor and via $W_L$ on the second factor.

The first two vertical arrows of the diagram (5.1) are $\widehat {W}^L$ -torsors while the right vertical arrow is $W_L$ -torsor.

Theorem 5.1. The complex ${\mathcal {N}}^L:=(q^L,p^L)_!{\overline {\mathbb {Q}}_{\ell }}$ is $\widehat {W}^L$ -equivariant (i.e., it descends to a complex ${\overline {{\mathcal {N}}}}_{\lambda }$ on $\overline {\mathcal {T}}_{\lambda }\times _{\mathfrak {car}_{\lambda }}\mathcal {G}_{\lambda }$ ).

Remark 5.2. We have the following commutative diagram

where the top square is cartesian. From this diagram we see that

$$ \begin{align*}{\overline{{\mathcal{N}}}}_{\lambda}|_{\mathcal{T}_{\lambda}\times_{\mathfrak{car}}\mathcal{G}_{\lambda}}\simeq{\mathcal{N}}|_{\mathcal{T}_{\lambda}\times_{\mathfrak{car}}\mathcal{G}_{\lambda}}=(q_{\lambda},p_{\lambda})_!{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

where ${\mathcal {N}}$ is as in §4. In other words, the complex ${\mathcal {N}}_{\lambda }:={\mathcal {N}}|_{\mathcal {T}_{\lambda }\times _{\mathfrak {car}}\mathcal {G}_{\lambda }}$ is W-equivariant.

5.2 Proof of Theorem 5.1

The essential case is when $L=G$ which case reduces to the nilpotent elements (see §4.3). We thus consider the following diagram:

and we want to prove that the complex $(q_{\mathrm {nil}},p_{\mathrm {nil}})_!{\overline {\mathbb {Q}}_{\ell }}$ is W-equivariant and so descends to $\mathrm {B}(N)\times \mathcal {G}_{\mathrm {nil}}$ .

Consider now the diagram

Notice that the complex $(q_{\mathrm {nil}},p_{\mathrm {nil}})_!{\overline {\mathbb {Q}}_{\ell }}$ is the restriction of $(\tau ,p)_!{\overline {\mathbb {Q}}_{\ell }}$ to $\mathrm {B}(T)\times \mathcal {G}_{\mathrm {nil}}$ .

It is thus enough to prove that $(\tau ,p)_!{\overline {\mathbb {Q}}_{\ell }}$ is W-equivariant.

The map $(\tau ,p)$ decomposes as

Following the strategy of §4.1, we see that the complex $(\tau ,p)_!{\overline {\mathbb {Q}}_{\ell }}$ is the outcome of the Postnikov diagram $\hat {p}_!\Lambda (\delta _!{\overline {\mathbb {Q}}_{\ell }})$ . The base of this Postnikov diagram is the complex

(5.2) $$ \begin{align} &{\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}})[-2n](-n)\overset{\partial_n}{\longrightarrow} X_*(T)\otimes{\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}})[2-2n](1-n)\overset{\partial_{n-1}}{\longrightarrow}\cdots \end{align} $$
$$\begin{align*} &\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad \ \cdots\overset{\partial_1}{\longrightarrow} \left(\bigwedge^nX_*(T)\right)\otimes{\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}}), \notag \end{align*}$$

where $\hat {\mathcal {L}}$ is the semisimple local system ${\overline {\mathbb {Q}}_{\ell }}\boxtimes \mathcal {L}$ with $\mathcal {L}=p_{{\mathrm {rss}}\, !}{\overline {\mathbb {Q}}_{\ell }}$ where $p_{\mathrm {rss}}:\mathcal {B}_{\mathrm {rss}}\rightarrow \mathcal {G}_{\mathrm {rss}}$ is the restriction of p to semisimple regular elements.

We consider on vertices of (5.2) the W-action given by the Springer action on ${\mathrm {IC}}_{\mathcal {G}}(\mathcal {L})=p_!{\overline {\mathbb {Q}}_{\ell }}$ and the obvious one on $X_*(T)$ .

Theorem 5.3. The arrows of the complex (5.2) are W-equivariant.

Theorem 5.3 will be a consequence of Theorem 5.6 below.

Corollary 5.4. The complex (5.2) descends to a unique complex $\overline {\Lambda }_b$ in $D_{\mathrm {c}}^{\mathrm {b}}(\hat {\mathcal {G}})$ whose vertices are

$$ \begin{align*}\left(\bigwedge^{2n-i}X_*(T)\right)\otimes\left(\overline{\mathbb{Q}}_{\ell,\, \mathrm{B}(N)}\boxtimes {\mathrm{IC}}_{\mathcal{G}}(\mathcal{L})\right)[2n-2i](n-i). \end{align*} $$

If $k_o$ is a finite subfield of k on which $G, T$ and B are defined, then $\overline {\Lambda }_b$ is naturally defined over $k_o$ .

Theorem 5.5. The complex $\overline {\Lambda }_b$ of Corollary 5.4 can be completed into a unique Postnikov diagram $\overline {\Lambda }$ (up to a unique isomorphism) such that for any finite subfield $k_o$ of k on which $G,T$ and B are defined, the diagram $\overline {\Lambda }$ is also defined over $k_o$ with $\overline {\Lambda }_b$ equipped with its natural $k_o$ -structure.

We have

$$ \begin{align*}\overline{\Lambda}|_{\hat{\mathcal{G}}}\simeq\hat{p}_!\Lambda(\delta_!{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

In particular, the outcome $(\tau ,p)_!{\overline {\mathbb {Q}}_{\ell }}$ of $\hat {p}_!\Lambda (\delta _!{\overline {\mathbb {Q}}_{\ell }})$ descends naturally to $\mathrm {B}(N)\times \mathcal {G}$ .

Proof. We choose a finite subfield $k_o$ on which G, T and B are defined. By the proof of Proposition 4.2, the conditions of Proposition 2.14 are satisfied over $k_o$ . Therefore, by Proposition 2.14, there is a unique Postnikov diagram $\overline {\Lambda }_o$ that completes the natural descent of $\overline {\Lambda }_b$ to $k_o$ . The wanted Postnikov diagram $\overline {\Lambda }$ is the one induced by $\overline {\Lambda }_o$ from $k_o$ to k.

As explained in §2.4, the group W acts on

$$ \begin{align*}{\mathrm{Ext}}^i_{\hat{\mathcal{G}}} \left({\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}}),{\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}})\right)=\mathrm{Hom}\left({\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}}), {\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}})[i]\right). \\[-15pt]\end{align*} $$

Theorem 5.6. The map

$$ \begin{align*}X^*(T)\overset{c_{\delta}}{\longrightarrow} H^2(\hat{\mathcal{B}},{\overline{\mathbb{Q}}_{\ell}})(1)={\mathrm{Ext}}^2_{\hat{\mathcal{B}}}({\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}})(1)\longrightarrow{\mathrm{Ext}}^2_{\hat{\mathcal{G}}}\left({\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}}),{\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}})\right)(1),\\[-15pt] \end{align*} $$

where the first arrow is the Chern class morphism of $\delta $ and the second arrow is given by $\hat {p}_!$ , is W-equivariant.

This is apriori not obvious as the natural action of W on $\hat {\mathcal {G}}$ does not lift to $\hat {\mathcal {B}}$ .

We have the following proposition.

Proposition 5.7. The Chern class morphism

$$ \begin{align*}c_{\delta}:X^*(T)\rightarrow H^2(\hat{\mathcal{B}},{\overline{\mathbb{Q}}_{\ell}})(1)\\[-15pt] \end{align*} $$

of the T-torsor $\delta $ is W-equivariant.

Proof. As $\hat {\mathcal {B}}=\mathrm {B}(T)\times \mathcal {B}$ , by Künneth formula we have

$$ \begin{align*}H^2(\hat{\mathcal{B}},{\overline{\mathbb{Q}}_{\ell}})(1)= H^2(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}})(1)\oplus H^2(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})(1). \end{align*} $$

Then

$$ \begin{align*}c_{\delta}=c_{\pi}\oplus -c_{\mathrm{can}},\\[-15pt] \end{align*} $$

where $\pi $ is the T-torsor $\dot {\mathcal {B}}\rightarrow \mathcal {B}$ . The Chern class morphism $c_{\mathrm {can}}$ of the trivial T-torsor $\mathrm {Spec}(k)\rightarrow \mathrm {B}(T)$ is W-equivariant.

We thus need to prove that $c_{\pi }$ is W-equivariant.

The Chern class morphism $c_{\pi }$ decomposes as

$$ \begin{align*}X^*(T)\rightarrow H^2(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})\simeq H^2(\mathrm{B}(B),{\overline{\mathbb{Q}}_{\ell}})\rightarrow H^2(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}}),\\[-15pt] \end{align*} $$

where the first map is $c_{\mathrm {can}}$ and the second map is the cohomological restriction of the canonical map $\mathcal {B}\rightarrow \mathrm {B}(B)$ . It is W-equivariant by Lemma 2.23.

Theorem 5.6 is a consequence of Proposition 5.7 together with the following one.

Proposition 5.8. The map

(5.3) $$ \begin{align} H^2(\hat{\mathcal{B}},{\overline{\mathbb{Q}}_{\ell}})(1)={\mathrm{Ext}}^2_{\hat{\mathcal{B}}}({\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}})(1)\rightarrow{\mathrm{Ext}}^2_{\hat{\mathcal{G}}}\left({\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}}),{\mathrm{IC}}_{\hat{\mathcal{G}}}(\hat{\mathcal{L}})\right)(1)\\[-15pt]\nonumber \end{align} $$

induced by $\hat {p}_!$ is W-equivariant.

Proof. By Künneth formula, we are reduced to prove that the same statement is true with $\hat {\mathcal {B}}$ and $\hat {\mathcal {G}}$ replaced by $\mathcal {B}$ and $\mathcal {G}$ . That is, we need to see that the map

(5.4) $$ \begin{align} H^2(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}})(1)={\mathrm{Ext}}^2_{\mathcal{B}}({\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}})(1)\rightarrow{\mathrm{Ext}}^2_{\mathcal{G}}\left({\mathrm{IC}}_{\mathcal{G}}(\mathcal{L}),{\mathrm{IC}}_{\mathcal{G}}(\mathcal{L})\right)(1) \end{align} $$

given by the functor $p_!$ is W-equivariant.

Consider the cartesian diagram

We have

$$ \begin{align*} {\mathrm{Ext}}^i_{\mathcal{G}}({\mathrm{IC}}_{\mathcal{G}}(\mathcal{L}),{\mathrm{IC}}_{\mathcal{G}}(\mathcal{L}))&=\mathrm{ Hom}(p_!{\overline{\mathbb{Q}}_{\ell}},p_!{\overline{\mathbb{Q}}_{\ell}}[i])\\ &=\mathrm{Hom}(p^*p_!{\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}}[i])\\ &=H^i(\mathcal{Z},\mathrm{pr}_1^!{\overline{\mathbb{Q}}_{\ell}})\\ &=H^{-i}_c(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

The dual of the map (5.4) is the cohomological restriction

$$ \begin{align*}H_c^{-2}(\mathcal{Z},{\overline{\mathbb{Q}}_{\ell}})\longrightarrow H_c^{-2}(\mathcal{B},{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

of the diagonal morphism $\mathcal {B}\rightarrow \mathcal {Z}$ . The proposition is thus a consequence of Theorem 3.4.

5.3 Descent over regular elements

We consider the diagram (4.1) over regular elements

and put

$$ \begin{align*}{\mathcal{N}}_{\mathrm{reg}}:=(q,p)_{{\mathrm{reg}}\, !}{\overline{\mathbb{Q}}_{\ell}}={\mathcal{N}}|_{\hat{{\mathcal{S}}}_{\mathrm{reg}}}. \end{align*} $$

Theorem 5.9. The kernel ${\mathcal {N}}_{\mathrm {reg}}$ is W-equivariant (i.e., it descends to ${\overline {\mathcal {T}}}\times _{\mathfrak {car}}\mathcal {G}_{\mathrm {reg}}$ ).

Proof. Following the strategy of §5.2, we need to prove that the base $\Lambda _b({\mathcal {N}}_{\mathrm {reg}})$ of the Postnikov diagram $\Lambda ({\mathcal {N}}_{\mathrm {reg}})$ is W-equivariant. With the map $\hat {f}_{\mathrm {reg}}$ being an isomorphism, the vertices of $\Lambda _b({\mathcal {N}}_{\mathrm {reg}})$ are constant sheaves (up to a shift) and so are clearly W-equivariant. To prove that the arrows are W-equivariant, we need to prove (analogously to Theorem 5.6) that the map

$$ \begin{align*}X^*(T)\longrightarrow H^2(\hat{\mathcal{B}}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}})(1)\longrightarrow{\mathrm{Ext}}^2(\hat{f}_{{\mathrm{reg}}\, !}{\overline{\mathbb{Q}}_{\ell}},\hat{f}_{{\mathrm{reg}}\, !}{\overline{\mathbb{Q}}_{\ell}})(1) \end{align*} $$

is W-equivariant. The first map being W-equivariant (see Proposition 5.7), we need to see that the second map too. However, notice that $\hat {f}_{\mathrm {reg}}$ is an isomorphism, and so the second map is an isomorphism

$$ \begin{align*}H^2(\hat{\mathcal{B}}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}})\longrightarrow H^2(\hat{{\mathcal{S}}}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

which is dual to the restriction morphism

$$ \begin{align*}H^{-2}_c(\hat{{\mathcal{S}}}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}})\longrightarrow H^{-2}_c(\hat{\mathcal{B}}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}}). \end{align*} $$

By Künneth formula, we are reduced to prove that the restriction map (which is an isomorphism)

$$ \begin{align*}H_c^{-2}({\mathcal{S}}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}})\longrightarrow H^{-2}_c(\mathcal{B}_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}})\\[-15pt] \end{align*} $$

is W-equivariant. Notice that $H_c^{-2}({\mathcal {S}}_{\mathrm {reg}},{\overline {\mathbb {Q}}_{\ell }})$ and $H^{-2}_c(\mathcal {B}_{\mathrm {reg}},{\overline {\mathbb {Q}}_{\ell }})$ are both the hypercohomology of the proper pushforwards of ${\overline {\mathbb {Q}}_{\ell }}$ along the maps $\mathrm {pr}_2:{\mathcal {S}}_{\mathrm {reg}}\rightarrow \mathcal {G}_{\mathrm {reg}}$ and $p_{\mathrm {reg}}:\mathcal {B}_{\mathrm {reg}}\rightarrow \mathcal {G}_{\mathrm {reg}}$ , respectively, and these pushforwards are the intermediate extensions of the pushforwards over semisimple regular elements. The result follows from the fact that W acts on $\mathcal {B}_{\mathrm {rss}}$ and that the isomorphism $\mathcal {B}_{\mathrm {rss}}\simeq {\mathcal {S}}_{\mathrm {rss}}$ is W-equivariant.

5.4 “Un calcul triste”

In this section we give an example where the kernel ${\mathcal {N}}$ is not W-equivariant.

5.10. Notice that if ${\mathcal {N}}$ were W-equivariant, then by Remark 2.12, the diagram $\Lambda ({\mathcal {N}})$ would be also W-equivariant and by Proposition 4.2(2), so would be the arrows of the complex $\Lambda _b({\mathcal {N}})$ .

For $w\in W$ , put $\mathcal {B}_w:=[\mathrm {Ad}(w){\mathfrak {b}}/wBw^{-1}]$ . We then have a cartesian diagram

from which we get a commutative diagram (base change)

where the horizontal arrows are given by the functors $(q^{\prime }_w,p_w)_!$ and $(q,p)_!$ , respectively. Identifying $H^2(\mathcal {B},{\overline {\mathbb {Q}}_{\ell }})$ and $H^2(\mathcal {B}_w,{\overline {\mathbb {Q}}_{\ell }})$ with $IH^2({\mathcal {S}},{\overline {\mathbb {Q}}_{\ell }})$ on one hand, and $(q',p)_!{\overline {\mathbb {Q}}_{\ell }}$ and $(q^{\prime }_w,p_w)_!{\overline {\mathbb {Q}}_{\ell }}$ with ${\mathrm {IC}}_{\mathcal {S}}$ on the other hand, we end up with a commutative diagram

Similarly to §5.2, we see that that the arrows of the diagram $\Lambda _b({\mathcal {N}})$ are W-equivariant if and only if $a=a_w$ for all $w\in W$ .

5.11. Assume that $G=\mathrm {SL}_2$ and put $a_-:=a_w$ for $w\neq 1$ and $a_+:=a$ . We prove below that $a_+\neq a_-$ , proving thus the nonequivariance of ${\mathcal {N}}$ .

Note that

$$ \begin{align*} &S:={\mathfrak{t}}\times_{\mathfrak{car}}{\mathfrak{g}}=\{(x,t)\in {\mathfrak{sl}}_2\times\mathbb{A}^1\,|\, \det(x)=-t^2\}\\ &X_+=\{(x,t,D)\in{\mathfrak{sl}}_2\times\mathbb{A}^1\times\mathbb{P}^1\,|\, (x,t)\in S, D\subset\mathrm{ Ker}(x-t\mathrm{Id})\}\\[-15pt] \end{align*} $$

and denote by $\rho _+:X_+\rightarrow S$ the map $(x,t,D)\mapsto (x,t)$ . We consider also the analogous map $\rho _-:X_-\rightarrow S$ , where we replace $\mathrm {Ker}(x-t\mathrm {Id})$ in the definition of $X_+$ by $\mathrm { Ker}(x+t\mathrm {Id})$ .

Note that if B denotes the Borel subgroup of upper triangular matrices, then

$$ \begin{align*}X_+\simeq \{(x,t,gB)\in{\mathfrak{sl}}_2\times\mathbb{A}^1\times \mathrm{SL}_2/B\,|\, g^{-1}xg\in(t,-t)+{\mathfrak{u}}\} \end{align*} $$

and $X_-$ corresponds to choosing the opposite Borel subgroup of lower triangular matrices.

We have compactifications

$$ \begin{align*} &\overline{S}:=\{(X;T;Z)\in\mathbb{P}^4\,|\, \det(X)=-T^2\}\\ &\overline{X}_+:=\{((X;T;Z),D)\in\overline{S}\times\mathbb{P}^1\,|\, D\subset\mathrm{Ker}(X-T\mathrm{Id})\}\\ &\overline{X}_-:=\{((X;T;Z),D)\in\overline{S}\times\mathbb{P}^1\,|\, D\subset\mathrm{Ker}(X+T\mathrm{Id})\}\ \end{align*} $$

where we identify ${\mathfrak {sl}}_2$ with $\mathbb {A}^3$ in the obvious way, and the small resolutions $\overline {\rho }_+:\overline {X}_+\rightarrow \overline {S}$ and $\overline {\rho }_-:\overline {X}_-\rightarrow \overline {S}$ .

Identifying $IH^2(\overline {S},{\overline {\mathbb {Q}}_{\ell }})$ with $H^2(\overline {X}_+,{\overline {\mathbb {Q}}_{\ell }})$ (resp. with $H^2(\overline {X}_-,{\overline {\mathbb {Q}}_{\ell }})$ ) and ${\mathrm {IC}}_{\overline {S}}$ with $\overline {\rho }_{+*}{\overline {\mathbb {Q}}_{\ell }}$ (resp. $\overline {\rho }_{-\, *}{\overline {\mathbb {Q}}_{\ell }}$ ) we get a map

$$ \begin{align*}\overline{a}_+:IH^2(\overline{S},{\overline{\mathbb{Q}}_{\ell}})\rightarrow{\mathrm{Ext}}^2\left({\mathrm{IC}}_{\overline{S}},{\mathrm{IC}}_{\overline{S}}\right)\end{align*} $$

(resp. we get a map $\overline {a}_-:IH^2(\overline {S},{\overline {\mathbb {Q}}_{\ell }})\rightarrow {\mathrm {Ext}}^2\left ({\mathrm {IC}}_{\overline {S}},{\mathrm {IC}}_{\overline {S}}\right )$ ).

If we compose $\overline {a}_+$ (resp. $\overline {a}_-$ ) with the natural map

$$ \begin{align*}{\mathrm{Ext}}^2\left({\mathrm{IC}}_{\overline{S}},{\mathrm{IC}}_{\overline{S}}\right)\rightarrow\mathrm{Hom}\left(IH^2(\overline{S},{\overline{\mathbb{Q}}_{\ell}}),IH^4(\overline{S},{\overline{\mathbb{Q}}_{\ell}})\right) \end{align*} $$

we get the cup-product

$$ \begin{align*}IH^2(\overline{S},{\overline{\mathbb{Q}}_{\ell}})\otimes IH^2(\overline{S},{\overline{\mathbb{Q}}_{\ell}})\overset{\smile_+}{\longrightarrow} IH^4(\overline{S},{\overline{\mathbb{Q}}_{\ell}}) \end{align*} $$

induced by the one on $H^*(\overline {X}_+,{\overline {\mathbb {Q}}_{\ell }})$ (resp. we get the cup-product $\smile _-$ induced by the one on $H^*(\overline {X}_-,{\overline {\mathbb {Q}}_{\ell }})$ ).

We have the following result [Reference Verdier20].

Proposition 5.12 (Verdier).

The two cup-products

are not the same.

Proof. For the convenience of the reader, we outline the proof.

Consider the following commutative diagram

Consider the divisors

$$ \begin{align*} &D_{1,+}:=\mathrm{pr}_+\left(f^{-1}(\{\infty\}\times\mathbb{P}^1)\right)=f_+^{-1}(\infty),\hspace{.5cm}D_{2,+}:=\mathrm{pr}_+\left(f^{-1}(\mathbb{P}^1\times\{\infty\})\right)\\ &D_{1,-}:=\mathrm{pr}_-\left(f^{-1}(\mathbb{P}^1\times\{\infty\})\right)=f_-^{-1}(\infty),\hspace{.5cm}D_{2,-}:=\mathrm{pr}_-\left(f^{-1}(\{\infty\}\times\mathbb{P}^1)\right)\\[-15pt] \end{align*} $$

Under the natural identifications

$$ \begin{align*}H^2(\overline{X}_+,{\overline{\mathbb{Q}}_{\ell}})\simeq IH^2(\overline{S},{\overline{\mathbb{Q}}_{\ell}})\simeq H^2(\overline{X}_-,{\overline{\mathbb{Q}}_{\ell}})\\[-15pt] \end{align*} $$

the class $\mathrm {cl}(D_{1,+/-})\in H^2(\overline {X}_{+/-},{\overline {\mathbb {Q}}_{\ell }})$ corresponds to $\mathrm { cl}(D_{2,-/+})\in H^2(\overline {X}_{-/+},{\overline {\mathbb {Q}}_{\ell }})$ , and so the proposition follows from the calculations

$$ \begin{align*}\mathrm{cl}(D_{1,+/-})\smile_{+/-}\mathrm{cl}(D_{1,+/-})=0,\hspace{.5cm}\mathrm{ cl}(D_{2,+/-})\smile_{+/-}\mathrm{cl}(D_{2,+/-})\neq 0.\\[-36pt] \end{align*} $$

As a consequence of the proposition, we get that the two maps $\overline {a}_+$ and $\overline {a}_-$ are different.

Let us now deduce from this that $a_+$ and $a_-$ are also different.

Put

$$ \begin{align*}K:=\underline{\mathrm{Hom}}({\mathrm{IC}}_{\overline{S}},{\mathrm{IC}}_{\overline{S}}).\\[-15pt] \end{align*} $$

Notice that

$$ \begin{align*}K|_S=\underline{\mathrm{Hom}}({\mathrm{IC}}_S,{\mathrm{IC}}_S).\\[-15pt] \end{align*} $$

Put

$$ \begin{align*} &\overline{\sigma}:=\overline{a}_+-\overline{a}_-:IH^2(\overline{S},{\overline{\mathbb{Q}}_{\ell}})\rightarrow {\mathrm{Ext}}^2({\mathrm{IC}}_{\overline{S}},{\mathrm{IC}}_{\overline{S}})=H^2(\overline{S},K)\\ &\sigma:=a_+-a_-:IH^2(S,{\overline{\mathbb{Q}}_{\ell}})\rightarrow {\mathrm{Ext}}^2({\mathrm{IC}}_S,{\mathrm{IC}}_S)=H^2(S,K|_S).\\[-15pt] \end{align*} $$

We have the following commutative diagram:

where the vertical arrows are the restriction maps.

Let $\overline {\alpha }\in IH^2(\overline {S},{\overline {\mathbb {Q}}_{\ell }})$ be such that $\overline {\sigma }(\overline {\alpha })\neq 0$ , and denote by $\alpha \in IH^2(S,{\overline {\mathbb {Q}}_{\ell }})$ the image of $\overline {\alpha }$ .

Proposition 5.13. We have

$$ \begin{align*}\sigma(\alpha)\neq 0\\[-15pt] \end{align*} $$

and so $a_+\neq a_-$ .

Proof. We need to prove that

(5.5) $$ \begin{align} \varphi_S\left(\overline{\sigma}(\overline{\alpha})\right)\neq 0. \end{align} $$

We have the open covering

$$ \begin{align*}\overline{S}=\overline{S}_{\mathrm{reg}}\cup S \end{align*} $$

where $\overline {S}_{\mathrm {reg}}$ is the smooth open subset of elements $(X;T;Z)$ in $\overline {S}$ such that $X\neq 0$ .

Notice that $S_{\mathrm {reg}}=\overline {S}_{\mathrm {reg}}\cap S$ , and so we have the exact sequence (Mayer-Vietoris)

$$ \begin{align*}\cdots\rightarrow H^1(S_{\mathrm{reg}},K|_{S_{\mathrm{reg}}})\rightarrow H^2(\overline{S},K)\overset{\varphi}{\longrightarrow} H^2(\overline{S}_{\mathrm{reg}},K|_{\overline{S}_{\mathrm{reg}}})\oplus H^2(S,K|_S)\rightarrow\cdots \end{align*} $$

Since $S_{\mathrm {reg}}$ and $\overline {S}_{\mathrm {reg}}$ are smooth open subsets of S and $\overline {S}$ , respectively, we have

$$ \begin{align*}K|_{S_{\mathrm{reg}}}=\underline{\mathrm{Hom}}_{S_{\mathrm{reg}}}({\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}})={\overline{\mathbb{Q}}_{\ell}},\hspace{.5cm}\text{ and }\hspace{.5cm} K|_{\overline{S}_{\mathrm{reg}}}={\overline{\mathbb{Q}}_{\ell}}. \end{align*} $$

Notice also that

$$ \begin{align*}H^1(S_{\mathrm{reg}},{\overline{\mathbb{Q}}_{\ell}})=0 \end{align*} $$

as $\rho |_{X_{\mathrm {reg}}}:X_{\mathrm {reg}}\simeq S_{\mathrm {reg}}$ and $H^1(X_{\mathrm {reg}},{\overline {\mathbb {Q}}_{\ell }})\simeq H^1(X,{\overline {\mathbb {Q}}_{\ell }})=0$ .

The map $\varphi $ is thus injective, and so to prove (5.5), we are reduced to prove that

$$ \begin{align*}\varphi_{\overline{S}_{\mathrm{reg}}}(\overline{\sigma}(\overline{\alpha}))= 0 \end{align*} $$

where $\varphi _{\overline {S}_{\mathrm {reg}}}:H^2(\overline {S},K)\rightarrow H^2(\overline {S}_{\mathrm {reg}},{\overline {\mathbb {Q}}_{\ell }})$ is the restriction map.

As the restrictions of $\overline {\rho }_+$ and $\overline {\rho }_-$ over regular elements induce isomorphisms $\overline {X}_{+,{\mathrm {reg}}}\simeq \overline {S}_{\mathrm {reg}}$ and $\overline {X}_{-,{\mathrm {reg}}}\simeq \overline {S}_{\mathrm {reg}}$ we have the following commutative diagram:

and the analogous diagram with $\overline {X}_-$ instead of $\overline {X}_+$ . From these two commutative diagrams we deduce that

$$ \begin{align*}\varphi_{\overline{S}_{\mathrm{reg}}}\circ \overline{\sigma}=0.\\[-36pt] \end{align*} $$

6 The functors $\mathrm {I}_{\lambda }$ and $\mathrm {R}_{\lambda }$

6.1 Definition

We consider the cohomological correspondence where $\mathrm {pr}_i$ is the i-th projection

with kernel ${\overline {{\mathcal {N}}}}_{\lambda }$ .

We define the associated restriction and induction functors

$$ \begin{align*} &\mathrm{R}_{\lambda}:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}_{\lambda})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}({\overline{\mathcal{T}}}_{\lambda}),\hspace{.5cm}K\mapsto\mathrm{pr}_{1!}\left(\mathrm{pr}_2^*(K)\otimes{\overline{{\mathcal{N}}}}_{\lambda}\right),\\ &\mathrm{I}_{\lambda}:D_{\mathrm{c}}^{\mathrm{b}}({\overline{\mathcal{T}}}_{\lambda})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}_{\lambda}),\hspace{.5cm}K\mapsto \mathrm{pr}_{2*}\,\underline{\mathrm{ Hom}}\left({\overline{{\mathcal{N}}}}_{\lambda},\mathrm{pr}_1^!(K)\right) \end{align*} $$

as in §2.5.

If we denote $\mathrm {Ind}_{\lambda }$ and $\mathrm {Res}_{\lambda }$ the induction and restriction functors associated to the correspondence

with kernel ${\mathcal {N}}_{\lambda }={\mathcal {N}}|_{\mathcal {T}_{\lambda }\times _{\mathfrak {car}}\mathcal {G}_{\lambda }}$ , then by Remark 5.2,

$$ \begin{align*}\mathrm{Ind}_{\lambda}=\mathrm{I}_{\lambda}\circ\pi_{\lambda\, *},\hspace{1cm}\mathrm{Res}_{\lambda}=\pi_{\lambda}^*\circ\mathrm{R}_{\lambda}.\\[-15pt] \end{align*} $$

Since $q_{\lambda }^!=q_{\lambda }^*$ and $p_{\lambda \,!}=p_{\lambda \, *}$ , we see that $\mathrm {Ind}_{\lambda }$ decomposes also as the composition of $\pi _{\lambda \, !}$ followed by the functor

$$ \begin{align*}D_{\mathrm{c}}^{\mathrm{b}}({\overline{\mathcal{T}}}_{\lambda})\rightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}_{\lambda}),\hspace{.5cm}K\mapsto \mathrm{pr}_{2!}\left(\mathrm{pr}_1^*(K)\otimes{\overline{{\mathcal{N}}}}_{\lambda}\right)\\[-15pt] \end{align*} $$

and so by Remark 2.17, we have

(6.1) $$ \begin{align} \mathrm{I}_{\lambda}(K)=\mathrm{pr}_{2!}\left(\mathrm{pr}_1^*(K)\otimes{\overline{{\mathcal{N}}}}_{\lambda}\right).\\[-15pt]\nonumber \end{align} $$

As in §2.9, we define a pair of adjoint functors $({^p}\mathrm {R}_{\lambda },{^p}\mathrm {I}_{\lambda })$

where $\overline {{\mathfrak {t}}}_{\lambda }:=[{\mathfrak {t}}_{\lambda }/W]$ . We let $\overline {s}_{\lambda }:{\overline {\mathcal {T}}}_{\lambda }\rightarrow \overline {{\mathfrak {t}}}_{\lambda }$ be the quotient map of the identity map ${\mathfrak {t}}_{\lambda }\rightarrow {\mathfrak {t}}_{\lambda }$ by $N\rightarrow W$ .

Lemma 6.1. We have

$$ \begin{align*}{^p}\mathrm{I}_{\lambda}=\mathrm{I}_{\lambda}\circ \overline{s}_{\lambda}^![n](n),\hspace{.5cm}{^p}\mathrm{R}_{\lambda}={^p}{\mathcal{H}}^0\circ \overline{s}_{\lambda\, !}\circ \mathrm{R}_{\lambda} [-n](-n). \end{align*} $$

Proof. Since the functors $\overline {s}_{\lambda }^![n](n)$ and ${^p}{\mathcal {H}}^0\circ \overline {s}_{\lambda \, !}[-n](-n)$ between $\mathcal {M}(\overline {{\mathfrak {t}}}_{\lambda })$ and $\mathcal {M}({\overline {\mathcal {T}}}_{\lambda })$ are inverse to each other, by adjunction we deduce the second equality from the first one.

Analogously to the definition ${^p}\underline {\mathrm {Ind}}$ (see §2.9) we define ${^p}\underline {\mathrm {Ind}}_{\lambda }$ by

$$ \begin{align*}{^p}\underline{\mathrm{Ind}}_{\lambda}:=\mathrm{Ind}_{\lambda}\circ s_{\lambda}^![n](n)={^p}\mathrm{I}_{\lambda}\circ \pi_{{\mathfrak{t}}_{\lambda}\, !}.\\[-15pt] \end{align*} $$

where

By Remark 2.17, to prove the first equality, we need to see that

$$ \begin{align*}{^p}\underline{\mathrm{Ind}}_{\lambda}=\mathrm{I}_{\lambda}\circ \overline{\mathrm{pr}}_{{\mathfrak{t}}_{\lambda}}^![n](n)\circ \pi_{{\mathfrak{t}}_{\lambda}\, !} \end{align*} $$

Using that $\mathrm {Ind}_{\lambda }=\mathrm {I}_{\lambda }\circ \pi _{\lambda \, !}$ , we are reduced to prove that

$$ \begin{align*}\overline{s}_{\lambda}^![n](n)\circ \pi_{{\mathfrak{t}}_{\lambda}\, !}=\pi_{\lambda\, !}\circ s_{\lambda}^![n](n). \end{align*} $$

But this follows from the base change theorem as $\overline {s}_{\lambda }$ and $s_{\lambda }$ are smooth and of the same relative dimension.

6.2 Semisimple regular elements

Let us see that $\mathrm {I}_{\lambda }$ and $\mathrm {R}_{\lambda }$ are the identity functors when $\lambda $ represents semisimple regular elements (i.e., when $\lambda $ is the conjugacy class of maximal tori), in which case we use the subscript ${\mathrm {rss}}$ instead of $\lambda $ in the notation.

Recall that

$$ \begin{align*}U\times{\mathfrak{t}}_{{\mathrm{reg}}}\longrightarrow{\mathfrak{b}}_{{\mathrm{rss}}},\hspace{.5cm}(u,t)\mapsto \mathrm{Ad}(u)(t) \end{align*} $$

is an isomorphism and so, taking the quotient by B on both sides, we end up with an isomorphism

$$ \begin{align*}\mathcal{T}_{{\mathrm{reg}}}\overset{\sim}{\longrightarrow}\mathcal{B}_{{\mathrm{rss}}}. \end{align*} $$

Moreover, the natural injection ${\mathfrak {t}}_{{\mathrm {reg}}}\rightarrow {\mathfrak {g}}_{{\mathrm {rss}}}$ induces an isomorphism

$$ \begin{align*}{\overline{\mathcal{T}}}_{\!{\mathrm{reg}}}\simeq\mathcal{G}_{{\mathrm{rss}}}. \end{align*} $$

Therefore, the morphism $(q_{\mathrm {rss}},p_{\mathrm {rss}})$ is the diagonal morphism

$$ \begin{align*}\mathcal{T}_{{\mathrm{reg}}}\longrightarrow\mathcal{T}_{{\mathrm{reg}}}\times_{\mathfrak{car}}\mathcal{G}_{{\mathrm{rss}}}=\mathcal{T}_{{\mathrm{reg}}}\times_{\mathfrak{car}}{\overline{\mathcal{T}}}_{\!{\mathrm{reg}}}. \end{align*} $$

We thus have the following cartesian diagram:

where the horizontal arrows are the quotient maps by W, and the vertical arrows are the diagonal morphisms (which are T-torsors). Therefore,

$$ \begin{align*}{\mathcal{N}}_{\mathrm{rss}}=(q_{\mathrm{rss}},p_{\mathrm{rss}})_!{\overline{\mathbb{Q}}_{\ell}}\simeq (\pi_{\mathrm{reg}}\times 1)^*\Delta_{{\overline{\mathcal{T}}}_{\!{\mathrm{reg}}}!}{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

(i.e., ${\overline {{\mathcal {N}}}}_{{\mathrm {rss}}}=\Delta _{{\overline {\mathcal {T}}}_{\!{\mathrm {reg}}}!}{\overline {\mathbb {Q}}_{\ell }}$ ). The functors $\mathrm {I}_{{\mathrm {rss}}}:D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\!{\mathrm {reg}}})\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{{\mathrm {rss}}})\simeq D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\!{\mathrm {reg}}})$ and $\mathrm {R}_{{\mathrm {rss}}}:D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\!{\mathrm {reg}}})\simeq D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{{\mathrm {rss}}})\rightarrow D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\!{\mathrm {reg}}})$ are thus the identity functors.

6.3 The isomorphism $\mathrm {R}_{\lambda }\circ \mathrm {I}_{\lambda }\simeq 1$

By (6.1) we can regard $\mathrm {I}_{\lambda }$ as a restriction functor. We thus consider the composition of correspondences

where the arrows are the obvious projections.

We put

$$ \begin{align*}{\overline{{\mathcal{N}}}}_{\lambda}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\lambda}:=\mathrm{pr}_{{\overline{\mathcal{T}}}_{\lambda},{\overline{\mathcal{T}}}_{\lambda} !}(\mathrm{pr}_{12}^*{\overline{{\mathcal{N}}}}_{\lambda}\otimes\mathrm{pr}_{23}^*{\overline{{\mathcal{N}}}}_{\lambda})=\mathrm{pr}_{{\overline{\mathcal{T}}}_{\lambda},{\overline{\mathcal{T}}}_{\lambda}!}({\overline{{\mathcal{N}}}}_{\lambda}\boxtimes_{\mathcal{G}_{\lambda}}{\overline{{\mathcal{N}}}}_{\lambda}). \end{align*} $$

Then it follows from §2.5 that the functor $\mathrm {R}_{\lambda }\circ \mathrm {I}_{\lambda }$ is the restriction functor of the cohomological correspondence

$$ \begin{align*}({\overline{\mathcal{T}}}_{\lambda}\times_{\mathfrak{car}_{\lambda}}{\overline{\mathcal{T}}}_{\lambda},{\overline{{\mathcal{N}}}}_{\lambda}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\lambda},a,b). \end{align*} $$

Theorem 6.2. There is a natural isomorphism

$$ \begin{align*}{\overline{{\mathcal{N}}}}_{\lambda}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\lambda}\overset{\simeq}{\longrightarrow}\Delta_{{\overline{\mathcal{T}}}_{\lambda}!}{\overline{\mathbb{Q}}_{\ell}}, \end{align*} $$

where

$$ \begin{align*}\Delta_{{\overline{\mathcal{T}}}_{\lambda}}:{\overline{\mathcal{T}}}_{\lambda}\rightarrow{\overline{\mathcal{T}}}_{\lambda}\times_{\mathfrak{car}_{\lambda}}{\overline{\mathcal{T}}}_{\lambda} \end{align*} $$

is the diagonal morphism. In particular we have $\mathrm {R}_{\lambda }\circ \mathrm {I}_{\lambda }\simeq 1$ .

As we did in §5.2, we explain the proof in the nilpotent case, which is the essential case. We thus consider the first diagram of §5.2, and we put

$$ \begin{align*}{\mathcal{N}}_{\mathrm{nil}}:=(q_{\mathrm{nil}},p_{\mathrm{nil}})_!{\overline{\mathbb{Q}}_{\ell}} \in D_{\mathrm{c}}^{\mathrm{b}}(\mathrm{B}(T)\times\mathcal{G}_{\mathrm{nil}}). \end{align*} $$

We have

$$ \begin{align*}({\overline{{\mathcal{N}}}}_{\mathrm{nil}}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\mathrm{nil}})|_{\mathrm{B}(T)\times\mathrm{B}(T)}=\mathrm{pr}_{\mathrm{B}(T),\mathrm{B}(T)\,!}({\mathcal{N}}_{\mathrm{nil}}\boxtimes_{\mathcal{G}_{\mathrm{nil}}}{\mathcal{N}}_{\mathrm{nil}}) \end{align*} $$

where

$$ \begin{align*}\mathrm{pr}_{\mathrm{B}(T),\mathrm{B}(T)}:\hat{{\mathcal{S}}}_{\mathrm{nil}}\times_{\mathcal{G}}\hat{{\mathcal{S}}}_{\mathrm{nil}}=\mathrm{B}(T)\times\mathcal{G}_{\mathrm{nil}}\times\mathrm{B}(T)\longrightarrow\mathrm{B}(T)\times\mathrm{B}(T) \end{align*} $$

is the obvious projection.

Consider the decomposition of $(q_{\mathrm {nil}},q_{\mathrm {nil}})$ as

By Künneth formula, we have

(6.2) $$ \begin{align} ({\overline{{\mathcal{N}}}}_{\mathrm{nil}}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\mathrm{nil}})|_{\mathrm{B}(T)\times\mathrm{B}(T)}=(q_{\mathrm{nil}},q_{\mathrm{nil}})_!{\overline{\mathbb{Q}}_{\ell}}. \end{align} $$

We consider the following commutative diagram

(6.3)

with diagonal morphisms $\Delta _{\mathcal {B}_{\mathrm {nil}}}$ and $\Delta _{\mathrm {B}(T)}$ .

The morphism $\Delta _{\mathcal {B}_{\mathrm {nil}}}:\mathcal {B}_{\mathrm {nil}}\rightarrow \mathcal {Z}_{\mathrm {nil}}$ is schematic closed, and so by adjunction we have a morphism

$$ \begin{align*}{\overline{\mathbb{Q}}_{\ell}}\rightarrow\Delta_{\mathcal{B}_{\mathrm{nil}}*}{\overline{\mathbb{Q}}_{\ell}}=\Delta_{\mathcal{B}_{\mathrm{nil}}!}{\overline{\mathbb{Q}}_{\ell}}, \end{align*} $$

and by applying the functor $(q_{\mathrm {nil}},q_{\mathrm {nil}})_!$ , we get a morphism

(6.4)

On the other hand, the morphism $q_{\mathrm {nil}}$ being smooth with fibres isomorphic to $[{\mathfrak {u}}/U]$ , we have by adjunction a morphism

(6.5)

which is an isomorphism, and so we obtain an isomorphism

(6.6)

Composing (6.4) with (6.6), we end up with a morphism

(6.7)

From (6.2) together with (6.7) we get a morphism

$$ \begin{align*}{\overline{{\mathcal{N}}}}_{\mathrm{nil}}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\mathrm{nil}}\longrightarrow(\pi_{\mathrm{nil}}\times\pi_{\mathrm{nil}})_!\Delta_{\mathrm{B}(T) !}{\overline{\mathbb{Q}}_{\ell}}=\Delta_{\mathrm{B}(N) !}\pi_{\mathrm{nil}\,!}{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

where $\pi _{\mathrm {nil}}$ is the canonical map $\mathrm {B}(T)\rightarrow \mathrm {B}(N)$ .

Composing with the adjunction morphism

$$ \begin{align*}\pi_{\mathrm{nil}\,!}(\pi_{\mathrm{nil}})^*=\pi_{\mathrm{nil}\,!}(\pi_{\mathrm{nil}})^!\longrightarrow 1 \end{align*} $$

we find

(6.8)

Consider the cartesian diagram

where the top arrow is given by $(w,t)\mapsto (w(t),t)$ and the bottom arrow is the diagonal morphism.

If we denote by $\Delta _{\mathrm {B}(T),w}:\mathrm {B}(T)\rightarrow \mathrm {B}(T)\times \mathrm {B}(T)$ the w-twisted diagonal morphism induced by $t\mapsto (w(t),t)$ , then

$$ \begin{align*}f_!{\overline{\mathbb{Q}}_{\ell}}=\bigoplus_{w\in W}\Delta_{\mathrm{B}(T),w\, !}{\overline{\mathbb{Q}}_{\ell}}=(\pi_{\mathrm{nil}}\times\pi_{\mathrm{nil}})^*\Delta_{\mathrm{B}(N)!}{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

and so the pullback of (6.8) along the map $\pi _{\mathrm {nil}}\times \pi _{\mathrm {nil}}$ provides a morphism

(6.9) $$ \begin{align} (q_{\mathrm{nil}},q_{\mathrm{nil}})_!{\overline{\mathbb{Q}}_{\ell}}\rightarrow\bigoplus_{w\in W}\Delta_{\mathrm{B}(T),w\,!}{\overline{\mathbb{Q}}_{\ell}}. \end{align} $$

of $W\times W$ -equivariant complexes.

Theorem 6.2 is thus a consequence of the following result.

Theorem 6.3. The morphism (6.9), and so the morphism (6.8), is an isomorphism.

It is enough to show that the morphism

$$ \begin{align*}{\mathcal{H}}^i(q_{\mathrm{nil}},q_{\mathrm{nil}})_!{\overline{\mathbb{Q}}_{\ell}}\rightarrow {\mathcal{H}}^i\left(\bigoplus_{w\in W}\Delta_{\mathrm{B}(T),w\,!}{\overline{\mathbb{Q}}_{\ell}}\right) \end{align*} $$

induced by the morphism (6.9) is an isomorphism for all i.

To prove this, we prove that we have an isomorphism

$$ \begin{align*}{\mathcal{H}}^i(q,q)_!{\overline{\mathbb{Q}}_{\ell}}\rightarrow {\mathcal{H}}^i\left(\bigoplus_{w\in W}\Delta_{\mathcal{T},w\,!}{\overline{\mathbb{Q}}_{\ell}}\right) \end{align*} $$

where $\Delta _{\mathcal {T},w}:\mathcal {T}\rightarrow \mathcal {T}\times _{\mathfrak {car}}\mathcal {T}$ is induced by $t\mapsto (w(t),t)$ .

Proposition 6.4. The sheaf ${\mathcal {H}}^i(q,q)_!{\overline {\mathbb {Q}}_{\ell }}$ is (up to a shift by $-n$ ) perverse and is the intermediate extension of its restriction to the open substack of regular elements of $\mathcal {T}\times _{\mathfrak {car}}\mathcal {T}$ . In particular, it is $W\times W$ -equivariant.

To prove the proposition, we will use a weight argument. Therefore, we choose a finite subfield $k_o$ of k such that $G, T,$ and B are defined over $k_o$ , and T is split over $k_o$ .

Recall that we have a stratification (see §3)

$$ \begin{align*}\mathcal{Z}=\coprod_{w\in W}\mathcal{Z}_w. \end{align*} $$

The restriction of $(q,q)$ to $\mathcal {Z}_w$ is the composition of the projection $q_w:\mathcal {Z}_w\rightarrow \mathcal {T}$ followed by the morphism $ \Delta _{\mathcal {T},w}:\mathcal {T}\rightarrow \mathcal {T}\times _{\mathfrak {car}}\mathcal {T}$ .

As the cohomology of $[{\mathfrak {u}}_w/U_w]$ is trivial, we deduce that

(6.10) $$ \begin{align} ((q,q)|_{\mathcal{Z}_w})_!{\overline{\mathbb{Q}}_{\ell}}=\Delta_{\mathcal{T},w\,!}{\overline{\mathbb{Q}}_{\ell}}. \end{align} $$

We choose a total order $\{w_0,w_1,\dots \}$ on W so that we have a decreasing filtration of closed substacks

$$ \begin{align*}\mathcal{Z}=\mathcal{Z}_0\supset\mathcal{Z}_1\supset\cdots\supset\mathcal{Z}_{|W|-1}\supset\mathcal{Z}_{|W|}=\emptyset \end{align*} $$

satisfying $\mathcal {Z}_i\backslash \mathcal {Z}_{i+1}=\mathcal {Z}_{w_i}$ for all i.

By [Reference Deligne5, Chapitre 6, 2.5], we have a spectral sequence

$$ \begin{align*}E_1^{ij}={\mathcal{H}}^{i+j}\left((q,q)|_{\mathcal{Z}_i\backslash\mathcal{Z}_{i+1}}\right)_!{\overline{\mathbb{Q}}_{\ell}}\Rightarrow {\mathcal{H}}^{i+j}(q,q)_!{\overline{\mathbb{Q}}_{\ell}}. \end{align*} $$

Lemma 6.5. This spectral sequence degenerates at $E_1$ .

Proof. As $\mathcal {Z}_i\backslash \mathcal {Z}_{i+1}=\mathcal {Z}_{w_i}$ and $\mathcal {T}=T\times \mathrm {B}(T)$ , by (6.10) we have

(6.11) $$ \begin{align} E_1^{ij}={\mathcal{H}}^{i+j}\Delta_{\mathcal{T},w_i\,!}{\overline{\mathbb{Q}}_{\ell}}=\bigwedge^{2n-i-j}X_*(T)\otimes\left(\Delta_{{\mathfrak{t}},w_i\, !}{\overline{\mathbb{Q}}_{\ell}}\boxtimes {{\overline{\mathbb{Q}}_{\ell}}}_{,\mathrm{B}(T)\times\mathrm{B}(T)}\right)(n-i-j) \end{align} $$

where $\Delta _{{\mathfrak {t}},w}:{\mathfrak {t}}\rightarrow {\mathfrak {t}}\times _{\mathfrak {car}} {\mathfrak {t}}$ is given by $t\mapsto (w(t),t)$ . Notice that

$$ \begin{align*}\Delta_{{\mathfrak{t}},w_i\,!}{\overline{\mathbb{Q}}_{\ell}}\boxtimes {{\overline{\mathbb{Q}}_{\ell}}}_{,\mathrm{B}(T)\times\mathrm{B}(T)} \end{align*} $$

is (up to a shift) perverse and pure of weight $0$ . Hence $E_1^{ij}$ is (up to a shift) pure of weight $2(i+j)$ .

Therefore, the sources and the targets of the differentials $d_1$ are (up to a shift) perverse of different weight, and so $d_1$ vanishes. We keep applying the same argument for the other differentials and we deduce that the spectral sequence degenerates at $E_1$ , i.e. $E_1=E_{\infty }$ .

Proof of Proposition 6.4.

It follows from Lemma 6.5 that ${\mathcal {H}}^k(q,q)_!{\overline {\mathbb {Q}}_{\ell }}$ is a successive extension of $E_1^{ij}$ ’s which are intermediate extensions of their restriction to the open substack of regular elements by (6.11). It is thus perverse (up to a shift by $-n$ ), and so the proposition is a consequence of Proposition 2.8.

Following the proof of (6.4), we have also a morphism

$$ \begin{align*}(q,q)_!{\overline{\mathbb{Q}}_{\ell}}\longrightarrow \Delta_{\mathcal{T}\, !}{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

where $\Delta _{\mathcal {T}}:\mathcal {T}\rightarrow \mathcal {T}\times _{\mathfrak {car}}\mathcal {T}$ is the diagonal morphism. We thus get a morphism

$$ \begin{align*}{\mathcal{H}}^i(q,q)_!{\overline{\mathbb{Q}}_{\ell}}\longrightarrow{\mathcal{H}}^i\Delta_{\mathcal{T}\, !}{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

and since, by Proposition 6.4, the sheaf ${\mathcal {H}}^i(q,q)_!{\overline {\mathbb {Q}}_{\ell }}$ is $W\times W$ -equivariant, we get a morphism

$$ \begin{align*}{\mathcal{H}}^i(q,q)_!{\overline{\mathbb{Q}}_{\ell}}\longrightarrow\bigoplus_{w\in W}{\mathcal{H}}^i\Delta_{\mathcal{T},w\, !}{\overline{\mathbb{Q}}_{\ell}}. \end{align*} $$

The source and the target of this morphism are intermediate extensions of their restriction to regular elements (see Proposition 6.4). It is thus an isomorphism, as its restriction to regular element is an isomorphism.

7 Main results

7.1 Derived categories

Fix $\lambda \in \mathfrak {L}$ . In this section we choose a geometric point $c:\mathrm {Spec}(k)\rightarrow \mathfrak {car}_{\lambda }$ . For any stack $\mathcal {X}$ above $\mathfrak {car}_{\lambda }$ we put

$$ \begin{align*}\mathcal{X}_c:=\mathrm{Spec}(k)\times_{\mathfrak{car}}\mathcal{X}, \end{align*} $$

and for any complex $K\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X})$ we denote by $K_c\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {X}_c)$ the pullback of K along the base change morphism $\mathcal {X}_c\rightarrow \mathcal {X}$ .

We have a commutative diagram with Cartesian squares

(7.1)

We then define the pair $(\mathrm {R}_c,\mathrm {I}_c)$ of adjoint functors

by

$$ \begin{align*}\mathrm{I}_c: K\mapsto\mathrm{pr}_{2!}({\overline{{\mathcal{N}}}}_c\otimes\mathrm{pr}_1^*(K)),\hspace{1cm}\mathrm{R}_c : K\mapsto\mathrm{pr}_{1!}({\overline{{\mathcal{N}}}}_c\otimes\mathrm{pr}_2^*(K)). \end{align*} $$

The following lemma follows from the base change theorem and the projection formula.

Lemma 7.1. We have the commutation formulas.

  1. (a)

    $$ \begin{align*}\iota_!\circ\mathrm{I}_c=\mathrm{I}_{\lambda}\circ\iota_!,\hspace{1cm}\mathrm{I}_c\circ\iota^*=\iota^*\circ\mathrm{I}_{\lambda}. \end{align*} $$
  2. (b)

    $$ \begin{align*}\iota_!\circ\mathrm{R}_c=\mathrm{R}_{\lambda}\circ\iota_!,\hspace{1cm}\mathrm{R}_c\circ\iota^*=\iota^*\circ\mathrm{R}_{\lambda}. \end{align*} $$

Theorem 7.2. We have

$$ \begin{align*}\mathrm{R}_c\circ\mathrm{I}_c\simeq 1.\hspace{1cm} \end{align*} $$

Proof. The isomorphism of functors $\mathrm {R}_c\circ \mathrm {I}_c\simeq 1$ is obtained by taking the pullback along $\overline {\mathcal {T}_c}\times \overline {\mathcal {T}_c}\rightarrow {\overline {\mathcal {T}}}_{\lambda }\times _{\mathfrak {car}_{\lambda }}{\overline {\mathcal {T}}}_{\lambda }$ of the isomorphism of complexes

$$ \begin{align*}{\overline{{\mathcal{N}}}}_{\lambda}\circ_{\mathcal{G}}{\overline{{\mathcal{N}}}}_{\lambda}\overset{\simeq}{\longrightarrow}\Delta_{{\overline{\mathcal{T}}}_{\lambda}\, !}{\overline{\mathbb{Q}}_{\ell}} \end{align*} $$

of Theorem 6.2.

We have also the functor

$$ \begin{align*}\mathrm{Ind}_c:D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{T}_c)\longrightarrow D_{\mathrm{c}}^{\mathrm{b}}(\mathcal{G}_c) \end{align*} $$

defined by base change from the diagram (2.20). It satisfies

$$ \begin{align*}\mathrm{Ind}_c=\mathrm{I}_c\circ\pi_{c\, !} \end{align*} $$

where $\pi _c$ is the W-torsor $\mathcal {T}_c\rightarrow {\overline {\mathcal {T}}}_c$ . When $c=0$ , we will use the notation $\pi _{\mathrm {nil}}$ instead of $\pi _c$ .

We define $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ as the triangulated subcategory of $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)$ generated by the simple direct factors of $\mathrm {Ind}_c({\overline {\mathbb {Q}}_{\ell }})$ which, by Springer theory, are indexed by the irreducible characters of the Weyl group $W_c$ of the centralizer of c.

Proposition 7.3. The functor $\mathrm {I}_c:D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_c)\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ induces a bijection between simple perverse sheaves compatible with parametrization by irreducible representations of $W_c$ .

Proof. The essential case is $c=0$ in which case we have $\mathcal {T}_c=\mathrm {B}(T)$ , ${\overline {\mathcal {T}}}_c=\mathrm {B}(N)$ and $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm { Spr}}=D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\mathrm {nil}})^{\mathrm {Spr}}$ . The simple objects of $D_{\mathrm {c}}^{\mathrm {b}}(\mathrm {B}(N))$ and $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\mathrm {nil}})^{\mathrm {Spr}}$ are both parametrized by the irreducible characters of W. This is Springer theory in the second case and, in the first case, the simple objects are the simple direct summands of $\pi _{\mathrm { nil}\,*}{\overline {\mathbb {Q}}_{\ell }}$ . The pullback functor $\overline {s}_{\mathrm {nil}}^![n](n)$ along the obvious morphism $\overline {s}_{\mathrm {nil}}:\mathrm {B}(N)\rightarrow \mathrm {B}(W)$ induces an equivalence between the categories of perverse sheaves that is compatible with the indexation of the simple perverse sheaves by the irreducible characters of W. By Lemma 6.1 applied to nilpotents, we have

$$ \begin{align*}{^p}\mathrm{I}_{\mathrm{nil}}=\mathrm{I}_{\mathrm{nil}}\circ\overline{s}_{\mathrm{nil}}^![n](n). \end{align*} $$

We are thus reduced to prove the statement of the proposition for ${^p}\mathrm {I}_{\mathrm { nil}}:\mathcal {M}(\mathrm {B}(W))\rightarrow \mathcal {M}(\mathcal {G}_{\mathrm {nil}})^{\mathrm {Spr}}$ . Unlike $\mathrm {I}_{\mathrm {nil}}$ , the construction of ${^p}\mathrm {I}_{\mathrm {nil}}$ extends to a global functor ${^p}\mathrm {I}$ . A standard argument using the functor ${^p}\mathrm {I}$ and its restriction to semisimple regular elements proves the proposition for ${^p}\mathrm {I}_{\mathrm {nil}}$ .

Proposition 7.4. The functor $\mathrm {I}_c$ induces an equivalence of categories $D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_c)\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ with inverse functor $\mathrm {R}_c$ .

Proof. Since $\mathrm {R}_c\circ \mathrm {I}_c\simeq 1$ , the functor $\mathrm {I}_c$ induces an injection between the $\mathrm {Ext}^i$ of simple perverse sheaves. On the other hand, by the proposition below together with [Reference Achar1, Theorem 4.6] and Proposition 7.3, we know that the $\mathrm { Ext}^i$ of the simple objects that corresponds under $\mathrm {I}_c$ have the same dimension and so $\mathrm {I}_c$ induces an isomorphism between the $\mathrm {Ext}^i$ . By a lemma of Beilinson [Reference Schnürer19, Lemma 6], the functor $\mathrm {I}_c$ induces thus an equivalence of categories $D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_c)\simeq D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ .

Consider the decomposition

$$ \begin{align*}\pi_{\mathrm{nil}\, !}{\overline{\mathbb{Q}}_{\ell}}=\bigoplus_{\varphi} V_{\varphi}\otimes \mathcal{L}_{\varphi} \end{align*} $$

where the sum runs over the irreducible ${\overline {\mathbb {Q}}_{\ell }}$ -characters of W, $V_{\varphi }$ is an irreducible representation affording the character $\varphi $ and the $\mathcal {L}_{\varphi }$ are the irreducible smooth $\ell $ -adic sheaves on $\mathrm {B}(N)$ .

Proposition 7.5. For any irreducible characters $\varphi $ and $\varphi '$ of W, we have

$$ \begin{align*}\mathrm{Ext}^i(\mathcal{L}_{\varphi},\mathcal{L}_{\varphi'})=\left(V_{\varphi}\otimes H^i(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})\otimes V_{\varphi'}^*\right)^W. \end{align*} $$

Proof. The proof is similar to that of [Reference Achar1, Theorem 4.6]. We give it for the convenience of the reader. We have

$$ \begin{align*} \mathrm{Ext}^i(\mathcal{L}_{\varphi},\mathcal{L}_{\varphi'})&=\mathrm{Hom}_W\left(V_{\varphi}^*,\mathrm{ Ext}^i(\pi_{\mathrm{nil}\,!}{\overline{\mathbb{Q}}_{\ell}},\mathcal{L}_{\varphi'})\right)\\ &=\mathrm{Hom}_W\left(V_{\varphi}^*,\mathrm{Ext}^i({\overline{\mathbb{Q}}_{\ell}},\pi_{\mathrm{nil}}^*(\mathcal{L}_{\varphi'}))\right)\\ &=\mathrm{Hom}_W\left(V_{\varphi}^*,\mathrm{ Ext}^i_{\mathrm{B}(T)}({\overline{\mathbb{Q}}_{\ell}},{\overline{\mathbb{Q}}_{\ell}})\otimes\mathrm{ Hom}({\overline{\mathbb{Q}}_{\ell}},\pi_{\mathrm{nil}}^*(\mathcal{L}_{\varphi'}))\right)\\ &=\mathrm{Hom}_W\left(V_{\varphi}^*,H^i(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})\otimes\mathrm{Hom}(\pi_{\mathrm{ nil}\,!}{\overline{\mathbb{Q}}_{\ell}},\mathcal{L}_{\varphi'})\right)\\ &=\left(V_{\varphi}\otimes H^i(\mathrm{B}(T),{\overline{\mathbb{Q}}_{\ell}})\otimes V_{\varphi'}^*\right)^W. \end{align*} $$

The third equality follows from the canonical isomorphism

$$ \begin{align*}\pi_{\mathrm{nil}}^*(\mathcal{L}_{\varphi'})\simeq {\overline{\mathbb{Q}}_{\ell}}\otimes\mathrm{ Hom}({\overline{\mathbb{Q}}_{\ell}},\pi_{\mathrm{nil}}^*(\mathcal{L}_{\varphi'})) \end{align*} $$

as the category $\mathcal {M}(\mathrm {B}(T))$ is semisimple linear with unique simple object ${\overline {\mathbb {Q}}_{\ell }}[-n]$ .

Define $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}$ as the full subcategory of $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })$ of complexes K such that $K_c\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ for all geometric point c of $\mathfrak {car}_{\lambda }$ .

Remark 7.6. If G is of type A with connected center then we have $D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}=D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })$ for all $\lambda $ .

Theorem 7.7. The functor $\mathrm {I}_{\lambda }$ induces an equivalence of categories $D_{\mathrm {c}}^{\mathrm {b}}({\overline {\mathcal {T}}}_{\lambda })\rightarrow D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}$ with inverse functor $\mathrm {R}_{\lambda }$ .

Proof. Since $\mathrm {R}_{\lambda }\circ \mathrm {I}_{\lambda }\simeq 1$ , it suffices to see that the morphism

$$ \begin{align*}K\longrightarrow \mathrm{I}_{\lambda}\circ\mathrm{R}_{\lambda}(K) \end{align*} $$

is an isomorphism for all $K\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_{\lambda })^{\mathrm {Spr}}$ . But it follows from the fact that it is true over $\mathcal {G}_c$ for any geometrical point c of $\mathfrak {car}_{\lambda }$ by the above proposition.

7.2 Perverse sheaves

Let $({^p}\mathrm {R},{^p}\mathrm {I})$ be the pair of adjoint functors defined in §2.9.

Theorem 7.8. The adjunction map

$$ \begin{align*}{^p}\mathrm{R}\circ{^p}\mathrm{I}\rightarrow 1 \end{align*} $$

is an isomorphism.

It is enough to prove that for any $\lambda \in \mathfrak {L}$ and any $K\in \mathcal {M}(\overline {{\mathfrak {t}}})$ , the restriction

$$ \begin{align*} \left({^p}\mathrm{R}\circ{^p}\mathrm{I}(K)\right)|_{{\overline{\mathcal{T}}}_{\lambda}}\rightarrow K|_{{\overline{\mathcal{T}}}_{\lambda}} \end{align*} $$

of the adjunction morphism ${^p}\mathrm {R}\circ {{}^p}\mathrm {I}(K)\rightarrow K$ along the map ${\overline {\mathcal {T}}}_{\lambda }\rightarrow \overline {{\mathfrak {t}}}$ is an isomorphism.

Therefore, the theorem is a consequence of Theorem 6.2 together with the following result, which is straightforward.

Proposition 7.9. For any $K\in \mathcal {M}(\overline {{\mathfrak {t}}})$ and $L\in \mathcal {M}(\mathcal {G})$ , we have

$$ \begin{align*} {{}^p}\mathrm{I}(K)|_{\mathcal{G}_{\lambda}}=\mathrm{I}_{\lambda}(K|_{{\overline{\mathcal{T}}}_{\lambda}})[-n],\hspace{1cm}{^p}\mathrm{R}(L)|_{{\overline{\mathcal{T}}}_{\lambda}}=\mathrm{R}_{\lambda}(L|_{\mathcal{G}_{\lambda}})[n]. \end{align*} $$

Denote by $\mathcal {M}(\mathcal {G})^{\mathrm {Spr}}$ the full subcategory if $\mathcal {M}(\mathcal {G})$ of perverse sheaves K such that $K_c\in D_{\mathrm {c}}^{\mathrm {b}}(\mathcal {G}_c)^{\mathrm {Spr}}$ for all geometric point c of $\mathfrak {car}$ .

Theorem 7.10. The functor ${^p}\mathrm {I}$ induces an equivalence of catgeories $\mathcal {M}(\overline {{\mathfrak {t}}})\rightarrow \mathcal {M}(\mathcal {G})^{\mathrm {Spr}}$ with inverse functor ${^p}\mathrm {R}$ .

In particular, if G is of type A with connected center, then $\mathcal {M}(\mathcal {G})^{\mathrm {Spr}}=\mathcal {M}(\mathcal {G})$ , and so the categories $\mathcal {M}(\overline {{\mathfrak {t}}})$ and $\mathcal {M}(\mathcal {G})$ are equivalent.

Proof. Thanks to Theorem 7.8, it remains to prove that

$$ \begin{align*}K\rightarrow {{}^p}\mathrm{I}\circ{{}^p}\mathrm{R}(K) \end{align*} $$

is an isomorphism for all $K\in \mathcal {M}(\mathcal {G})^{\mathrm {Spr}}$ . We are thus reduced to prove that this is an isomorphism after restriction to $\mathcal {G}_{\lambda }$ for all $\lambda \in \mathfrak {L}$ . But this is a consequence of Proposition 7.9 and Theorem 7.7.

Acknowledgements

It is a pleasure to thank P. Achar, O. Dudas, S. Gunningham, B. Hennion, L. Illusie, B. Keller and O. Schiffmann for useful discussions, O. Gabber for telling us about Verdier’s paper “Un calcul triste” and M. Romagny for his help with group action on stacks.

Conflict of Interest

The authors have no conflict of interest to declare.

References

Achar, P., ‘Green functions via hyperbolic localization’, Doc. Math. 16 (2011), 869884.CrossRefGoogle Scholar
Beilinson, A. A., Bernstein, J. and Deligne, P., ‘Faisceaux pervers, Analysis and topology on singular spaces, I (Luminy, 1981)’, Soc . Math. France, Paris (1982), 5171.Google Scholar
Bezrukavnikov, R. and Yom Din, A., ‘On parabolic restriction of perverse sheaves’, Publ. Res. Inst. Math. Sci 57 (2021), 10891107.CrossRefGoogle Scholar
Borho, W. and MacPherson, R., ‘Représentations des groupes de Weyl et homologie d’intersection pour les variétés nilpotentes’, C. R. Acad. Sci. Paris 292 (1981), 707710.Google Scholar
Deligne, P., ‘Cohomologie étale: Séminaire de géométrie algébrique du Bois-Marie SGA 412 ’, Lecture Notes in Mathematics vol. 569 (Springer-Verlag, Berlin, 1977).CrossRefGoogle Scholar
Gunningham, S., ‘A derived decomposition for equivariant D-modules’, arXiv:1705.04297.Google Scholar
Gunningham, S., ‘Generalized Springer theory for D-modules on a reductive Lie algebra’, Sel. Math. New Ser. 24(5) (2018), 42234277.CrossRefGoogle Scholar
Kiehl, R. and Weissauer, R., ‘Weil conjectures, perverse sheaves and l’adic Fourier transform’, A Series of Modern Surveys in Mathematics vol.42 (Springer-Verlag, 2001).CrossRefGoogle Scholar
Laszlo, Y. and Olsson, M., ‘The six operations for sheaves on Artin stacks II: Adic Coefficients’, Publ. Math. Inst. Hautes Etudes Sci. 107 (2008), 169210.CrossRefGoogle Scholar
Le, J. and Chen, X.-W., ‘Karoubianness of a triangulated category’, J. Algebra 310 (2007), 452457.CrossRefGoogle Scholar
Letellier, E., ‘Fourier transforms of Invariant functions on finite reductive Lie algebras ’, Lecture Notes in Mathematics vol. 1859 (Springer-Verlag, Berlin, 2005).CrossRefGoogle Scholar
Li, P., ‘Derived categories of character sheaves’, arXiv:1803.04289 (2018).Google Scholar
Lusztig, G., ‘Intersection cohomology complexes on a reductive group’, Invent. Math. 75 (1984), 205272.CrossRefGoogle Scholar
Lusztig, G., ‘Character sheaves II’, Adv. in Math. 57 (1985), 226265.CrossRefGoogle Scholar
Lusztig, G., ‘Character sheaves on disconnected groups. III’, Represent. Theory 8 (2004), 125144.CrossRefGoogle Scholar
Orlov, D. O., ‘Equivalence of derived categories and K3 surfaces’, J. Math. Sciences 84 (1997), 13611381.CrossRefGoogle Scholar
Rider, L., ‘Formality for the nilpotent cone and a derived Springer correspondence’, Adv. Math. 235 (2013), 208236.CrossRefGoogle Scholar
Romagny, M., ‘Group Actions on Stacks and Applications’, Michigan Math. J. 53 (2005), 209236.CrossRefGoogle Scholar
Schnürer, O., ‘Equivariant sheaves on flag varieties’, Math. Z. 267 (2011), 2780.CrossRefGoogle Scholar
Verdier, J.-L., ‘ Un calcul triste . Appendice, Géométrie algébrique et applications: II. Singularités et géométrie complexe’, Travaux en cours 23 (1987), 1214, Hermann.Google Scholar