Equivariant sheaf explained

\sigma:G x SX\toX

of a group scheme G on a scheme X over a base scheme S, an equivariant sheaf F on X is a sheaf of

l{O}X

-modules
together with the isomorphism of
l{O}
G x SX
-modules

\phi:\sigma*F\xrightarrow{\simeq}

*F
p
2
 

that satisfies the cocycle condition: writing m for multiplication,

*
p
23

\phi\circ(1G x \sigma)*\phi=(m x

*
1
X)

\phi

.

Notes on the definition

On the stalk level, the cocycle condition says that the isomorphism

Fgh\simeqFx

is the same as the composition

Fg\simeqFh\simeqFx

; i.e., the associativity of the group action. The condition that the unit of the group acts as the identity is also a consequence: apply

(e x e x 1)*,e:S\toG

to both sides to get

(e x 1)*\phi\circ(e x 1)*\phi=(e x 1)*\phi

and so

(e x 1)*\phi

is the identity.

Note that

\phi

is an additional data; it is "a lift" of the action of G on X to the sheaf F. Moreover, when G is a connected algebraic group, F an invertible sheaf and X is reduced, the cocycle condition is automatic: any isomorphism

\sigma*F\simeq

*
p
2

F

automatically satisfies the cocycle condition (this fact is noted at the end of the proof of Ch. 1, § 3., Proposition 1.5. of Mumford's "geometric invariant theory.")

If the action of G is free, then the notion of an equivariant sheaf simplifies to a sheaf on the quotient X/G, because of the descent along torsors.

By Yoneda's lemma, to give the structure of an equivariant sheaf to an

l{O}X

-module F is the same as to give group homomorphisms for rings R over

S

,

G(R)\to\operatorname{Aut}(X x S\operatorname{Spec}R,FSR)

.

There is also a definition of equivariant sheaves in terms of simplicial sheaves. Alternatively, one can define an equivariant sheaf to be an equivariant object in the category of, say, coherent sheaves.

Linearized line bundles

A structure of an equivariant sheaf on an invertible sheaf or a line bundle is also called a linearization.

Let X be a complete variety over an algebraically closed field acted by a connected reductive group G and L an invertible sheaf on it. If X is normal, then some tensor power

Ln

of L is linearizable.

Also, if L is very ample and linearized, then there is a G-linear closed immersion from X to

PN

such that
l{O}
PN

(1)

is linearized and the linearlization on L is induced by that of
l{O}
PN

(1)

.

Tensor products and the inverses of linearized invertible sheaves are again linearized in the natural way. Thus, the isomorphism classes of the linearized invertible sheaves on a scheme X form an abelian group. There is a homomorphism to the Picard group of X which forgets the linearization; this homomorphism is neither injective nor surjective in general, and its kernel can be identified with the isomorphism classes of linearizations of the trivial line bundle.

See Example 2.16 of https://www-fourier.ujf-grenoble.fr/~mbrion/linearization for an example of a variety for which most line bundles are not linearizable.

Dual action on sections of equivariant sheaves

Given an algebraic group G and a G-equivariant sheaf F on X over a field k, let

V=\Gamma(X,F)

be the space of global sections. It then admits the structure of a G-module; i.e., V is a linear representation of G as follows. Writing

\sigma:G x X\toX

for the group action, for each g in G and v in V, let

\pi(g)v=(\varphi\circ\sigma*)(v)(g-1)

where

\sigma*:V\to\Gamma(G x X,\sigma*F)

and

\varphi:\Gamma(G x X,\sigma*F)\overset{\sim}\to\Gamma(G x X,

*
p
2

F)=k[G]kV

is the isomorphism given by the equivariant-sheaf structure on F. The cocycle condition then ensures that

\pi:G\toGL(V)

is a group homomorphism (i.e.,

\pi

is a representation.)

Example: take

X=G,F=l{O}G

and

\sigma=

the action of G on itself. Then

V=k[G]

,

(\varphi\circ\sigma*)(f)(g,h)=f(gh)

and

(\pi(g)f)(h)=f(g-1h)

,meaning

\pi

is the left regular representation of G.

The representation

\pi

defined above is a rational representation: for each vector v in V, there is a finite-dimensional G-submodule of V that contains v.

Equivariant vector bundle

A definition is simpler for a vector bundle (i.e., a variety corresponding to a locally free sheaf of constant rank). We say a vector bundle E on an algebraic variety X acted by an algebraic group G is equivariant if G acts fiberwise: i.e.,

g:Ex\toEgx

is a "linear" isomorphism of vector spaces.[1] In other words, an equivariant vector bundle is a pair consisting of a vector bundle and the lifting of the action

G x X\toX

to that of

G x E\toE

so that the projection

E\toX

is equivariant.

Just like in the non-equivariant setting, one can define an equivariant characteristic class of an equivariant vector bundle.

Examples

See also

References

External links

Notes and References

  1. If E is viewed as a sheaf, then g needs to be replaced by

    g-1

    .