Leray spectral sequence

Let f:X→Y be a continuous map of topological spaces, which in particular gives a functor f_* from sheaves on X to sheaves on Y. Composing this with the functor Γ of taking sections on Sh(Y) is the same as taking sections on Sh(X), by the definition of the direct image functor f_*:

${\displaystyle {\ce {Sh}}(X)\ {\ce {->[f_*] Sh}}(Y)\ {\ce {->[\Gamma] Ab}}}$

Thus the derived functors of Γ f_* compute the sheaf cohomology for X:

${\displaystyle R^{i}(\Gamma \cdot f_{*})({\mathcal {F}})=H^{i}(X,{\mathcal {F}})}$

But because f_* and Γ satisfy certain conditions, there is a spectral sequence whose second page

${\displaystyle E_{2}^{pq}=(R^{p}\Gamma \cdot R^{q}f_{*})({\mathcal {F}})=H^{p}(Y,R^{q}f_{*}({\mathcal {F}}))}$

and which converges to

${\displaystyle E_{\infty }^{pq}\ \ \ =\ \ \ R^{p+q}(\Gamma \cdot f_{*})({\mathcal {F}})=H^{p+q}(X,{\mathcal {F}})}$

This is called the Leray spectral sequence.

For a proof of the existence of a spectral sequence under the conditions alluded to above, see Grothendieck spectral sequence.

Let f:X→Y be a continuous map of smooth manifolds. If U={U_i} is an open cover of Y, form the Cech complex with respect to cover f⁻¹U of X:

${\displaystyle {\text{C}}^{p}(f^{-1}{\mathcal {U}},{\mathcal {F}})}$

The boundary maps d_p:C^p→C^p+1 and maps δ_q:Ω_X^q→Ω_X^q+1 of sheaves on X together give a boundary map on the double complex C^p(f⁻¹U,Ω^q)

${\displaystyle D=d+\delta \$ :\ C^{\bullet }(f^{-1}{\mathcal {U}},\Omega _{X}^{\bullet })\longrightarrow C^{\bullet }(f^{-1}{\mathcal {U}},\Omega _{X}^{\bullet })}

This double complex is also a single complex graded by ${\displaystyle n=p+q}$, with respect to which D is a boundary map. If each finite intersection of the U_i is diffeomorphic to Rⁿ, one can show that the cohomology

${\displaystyle H_{D}^{n}(C^{\bullet }(f^{-1}{\mathcal {U}},\Omega _{X}^{\bullet }))=H_{\text{dR}}^{n}(X,\mathbb {R} )}$

of this complex is the de Rham cohomology of X.[3] Moreover,[4][5] any double complex has a spectral sequence E with

${\displaystyle E_{\infty }^{n-p,p}\ \ \ =\ \ \ {\text{ the }}p{\text{th graded part of }}H_{D}^{n}(C^{\bullet }(f^{-1}{\mathcal {U}},\Omega _{X}^{\bullet }))}$

(so that the sum of these is Hⁿ_D), and

${\displaystyle E_{2}^{p,q}\ \ \ =\ \ \ H^{p}(f^{-1}{\mathcal {U}},{\mathcal {H}}^{q})}$

where ${\displaystyle {\mathcal {H}}^{q}}$ is the presheaf on X sending V→H^q(f⁻¹V). In this context, this is called the Leray spectral sequence.

The modern definition subsumes this, because the higher direct image functor ${\displaystyle R^{p}f_{*}(F)}$ is the sheafification of the presheaf V→H^q(f⁻¹V,F).

• Let X,F be smooth manifolds, and X be simply connected. We calculate the Leray spectral sequence of the projection p:X×F→X. If the cover U = {U_i} is good (finite intersections are Rⁿ) then

${\displaystyle {\mathcal {H}}^{p}(f^{-1}U_{i})\simeq H^{q}(F)}$

Since X is simply connected, any locally constant presheaf is constant, so this is the constant presheaf H^q(F) = Rⁿ. So the second page of the Leray spectral sequence is

${\displaystyle E_{2}^{p,q}=H^{p}(f^{-1}{\mathcal {U}},H^{q}(F))=H^{p}(f^{-1}{\mathcal {U}},\mathbb {R} )\otimes H^{q}(F)}$

As the cover f⁻¹U of X×F is also good, H^p(f⁻¹U,R) = H^p(X). So

${\displaystyle E_{2}^{p,q}=H^{p}(X)\otimes H^{q}(F)\ \ \ \Longrightarrow \ \ \ H^{p+q}(X\times F,\mathbb {R} )}$

Here is the first place we use that p is a projection and not just a fibre bundle: every element of E₂ is an actual closed differential form on all of X×F, so applying both d and δ to them gives zero. Thus E_∞ = E₂. This proves the Kunneth theorem for X simply connected:

${\displaystyle H^{\bullet }(X\times Y,\mathbb {R} )\simeq H^{\bullet }(X)\otimes H^{\bullet }(Y)}$

• If p:Y→X is a general fibre bundle with fibre F, the above applies, except that V^p→H^p(f⁻¹V,H^q) is only a locally constant presheaf, not constant.
• All example computations with the Serre spectral sequence are the Leray sequence for the constant sheaf.

In the category of quasi-projective varieties over C, there is a degeneration theorem proved by Deligne–Blanchard for the Leray which states that a smooth projective morphism of varieties ${\displaystyle f:X\to Y}$ gives us that the ${\displaystyle E_{2}}$-page of the spectral sequence for ${\displaystyle {\underline {\mathbb {Q} }}_{X}}$ degenerates, hence

${\displaystyle H^{k}(X;\mathbb {Q} )\cong \bigoplus _{p+q=k}H^{p}(Y;\mathbf {R} ^{q}f_{*}({\underline {\mathbb {Q} }}_{X}))}$

Easy examples can be computed if Y is simply connected; for example a complete intersection of dimension ${\displaystyle \geq 2}$ (this is because of the Hurewicz morphism and the Lefschetz hyperplane theorem). In this case the local systems ${\displaystyle \mathbf {R} ^{q}f_{*}({\underline {\mathbb {Q} }}_{X})}$ will have trivial monodromy, hence ${\displaystyle \mathbf {R} ^{q}f_{*}({\underline {\mathbb {Q} }}_{X})\cong {\underline {\mathbb {Q} }}_{Y}^{\oplus l_{q}}}$. For example, consider a smooth family ${\displaystyle f:X\to Y}$ of genus 3 curves over a smooth K3 surface. Then, we have that

${\displaystyle {\begin{aligned}\mathbf {R} ^{0}f_{*}({\underline {\mathbb {Q} }}_{Y})&\cong {\underline {\mathbb {Q} }}_{Y}\\\mathbf {R} ^{1}f_{*}({\underline {\mathbb {Q} }}_{Y})&\cong {\underline {\mathbb {Q} }}_{Y}^{\oplus 6}\\\mathbf {R} ^{2}f_{*}({\underline {\mathbb {Q} }}_{Y})&\cong {\underline {\mathbb {Q} }}_{Y}\end{aligned}}}$

giving us the ${\displaystyle E_{2}}$-page

${\displaystyle E_{2}=E_{\infty }={\begin{bmatrix}H^{0}(Y;{\underline {\mathbb {Q} }}_{Y})&0&H^{2}(Y;{\underline {\mathbb {Q} }}_{Y})&0&H^{4}(Y;{\underline {\mathbb {Q} }}_{Y})\\H^{0}(Y;{\underline {\mathbb {Q} }}_{Y}^{\oplus 6})&0&H^{2}(Y;{\underline {\mathbb {Q} }}_{Y}^{\oplus 6})&0&H^{4}(Y;{\underline {\mathbb {Q} }}_{Y}^{\oplus 6})\\H^{0}(Y;{\underline {\mathbb {Q} }}_{Y})&0&H^{2}(Y;{\underline {\mathbb {Q} }}_{Y})&0&H^{4}(Y;{\underline {\mathbb {Q} }}_{Y})\end{bmatrix}}}$

At the time of Leray's work, neither of the two concepts involved (spectral sequence, sheaf cohomology) had reached anything like a definitive state. Therefore it is rarely the case that Leray's result is quoted in its original form. After much work, in the seminar of Henri Cartan in particular, the modern statement was obtained, though not the general Grothendieck spectral sequence.

Earlier (1948/9) the implications for fiber bundles were extracted in a form formally identical to that of the Serre spectral sequence, which makes no use of sheaves. This treatment, however, applied to Alexander–Spanier cohomology with compact supports, as applied to proper maps of locally compact Hausdorff spaces, as the derivation of the spectral sequence required a fine sheaf of real differential graded algebras on the total space, which was obtained by pulling back the de Rham complex along an embedding into a sphere. Serre, who needed a spectral sequence in homology that applied to path space fibrations, whose total spaces are almost never locally compact, thus was unable to use the original Leray spectral sequence and so derived a related spectral sequence whose cohomological variant agrees, for a compact fiber bundle on a well-behaved space with the sequence above.

In the formulation achieved by Alexander Grothendieck by about 1957, the Leray spectral sequence is the Grothendieck spectral sequence for the composition of two derived functors.

• Leray spectral sequence Article in the Encyclopedia of Mathematics