Decomposition theorem of Beilinson, Bernstein and Deligne explained

In mathematics, especially algebraic geometry, the decomposition theorem of Beilinson, Bernstein and Deligne or BBD decomposition theorem is a set of results concerning the cohomology of algebraic varieties. It was originally conjectured by Gelfand and MacPherson.^[1]

Statement

Decomposition for smooth proper maps

The first case of the decomposition theorem arises via the hard Lefschetz theorem which gives isomorphisms, for a smooth proper map

f:X\toY

of relative dimension d between two projective varieties

-\cupηⁱ:R^d-if_*(Q)\stackrel\cong\toR^d+if_*(Q).

Here

is the fundamental class of a hyperplane section,

f_*

is the direct image (pushforward) and

Rⁿf_*

is the n-th derived functor of the direct image. This derived functor measures the n-th cohomologies of

f^-1(U)

, for

U\subsetY

.In fact, the particular case when Y is a point, amounts to the isomorphism

-\cupηⁱ:H^d-i(X,Q)\stackrel\cong\toH^d+i(X,Q).

This hard Lefschetz isomorphism induces canonical isomorphisms

Rf_*(Q)\stackrel\cong\to

	d
oplus
	i=-d

R^d+if_*(Q)[-d-i].

Moreover, the sheaves

R^d+if_*Q

appearing in this decomposition are local systems, i.e., locally free sheaves of Q-vector spaces, which are moreover semisimple, i.e., a direct sum of local systems without nontrivial local subsystems.

Decomposition for proper maps

The decomposition theorem generalizes this fact to the case of a proper, but not necessarily smooth map

f:X\toY

between varieties. In a nutshell, the results above remain true when the notion of local systems is replaced by perverse sheaves.

The hard Lefschetz theorem above takes the following form:^[2] ^[3] there is an isomorphism in the derived category of sheaves on Y:

{}^pH^-i(Rf_*Q)\cong{}^pH⁺ⁱ(Rf_*Q),

where

Rf_*

is the total derived functor of

f_*

and

{}^pHⁱ

is the i-th truncation with respect to the perverse t-structure.

Moreover, there is an isomorphism

Rf_*

	\bullet
IC
	X

\congoplus_i{}^pHⁱ(Rf_*

	\bullet)[-i].
IC
	X

where the summands are semi-simple perverse-sheaves, meaning they are direct sums of push-forwards of intersection cohomology sheaves.

If X is not smooth, then the above results remain true when

Q[\dimX]

is replaced by the intersection cohomology complex

Proofs

The decomposition theorem was first proved by Beilinson, Bernstein, and Deligne.^[4] Their proof is based on the usage of weights on l-adic sheaves in positive characteristic. A different proof using mixed Hodge modules was given by Saito. A more geometric proof, based on the notion of semismall maps was given by de Cataldo and Migliorini.^[5]

For semismall maps, the decomposition theorem also applies to Chow motives.

Applications of the theorem

Cohomology of a Rational Lefschetz Pencil

Consider a rational morphism

f:X → P¹

from a smooth quasi-projective variety given by

[f_1(x):f_2(x)]

. If we set the vanishing locus of

f_1,f₂

then there is an induced morphism

\tilde{X}=Bl_Y(X)\toP¹

. We can compute the cohomology of

from the intersection cohomology of

Bl_Y(X)

and subtracting off the cohomology from the blowup along

. This can be done using the perverse spectral sequence

	l,m
E
	2

=H^l(P^1;{}^ak{p}l{H}

	m(IC

	\tilde{X

}^\bullet(\mathbb)) \Rightarrow IH^(\tilde;\mathbb) \cong H^(X;\mathbb)

Local invariant cycle theorem

Let

f:X\toY

be a proper morphism between complex algebraic varieties such that

is smooth. Also, let

y₀

be a regular value of

that is in an open ball B centered at

. Then the restriction map

\operatorname{H}^*(f^-1(y),Q)=\operatorname{H}^*(f^-1(B),Q)\to\operatorname{H}^*(f^-1(y_0),

	\pi_1,
Q)

}is surjective, where

\pi_1,

} is the fundamental group of the intersection of

with the set of regular values of f.

References

Survey Articles

- - Web site: R. . MacPherson . Intersection homology and perverse sheaves . 1990 .

Pedagogical References

Notes and References

Conjecture 2.10. of Sergei Gelfand & Robert MacPherson, Verma modules and Schubert cells: A dictionary.
. NB: To be precise, the reference is for the decomposition.
NB: To be precise, the reference is for the decomposition.
Beilinson. Alexander A.. Alexander Beilinson. Joseph Bernstein. Joseph . Bernstein. Pierre Deligne. Pierre . Deligne. 1982. Faisceaux pervers. Astérisque. 100. Société Mathématique de France, Paris. French.
de Cataldo. Mark Andrea. Mark de Cataldo. Migliorini. Luca. The Hodge theory of algebraic maps. Annales Scientifiques de l'École Normale Supérieure. 38. 5. 693–750. 2005. 10.1016/j.ansens.2005.07.001. math/0306030. 2003math......6030D. 54046571.

Decomposition theorem of Beilinson, Bernstein and Deligne explained

Statement

Decomposition for smooth proper maps

Decomposition for proper maps

Proofs

Applications of the theorem

Cohomology of a Rational Lefschetz Pencil

Local invariant cycle theorem

References

Survey Articles

Pedagogical References

Further reading

Notes and References