Lyndon–Hochschild–Serre spectral sequence

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In mathematics, especially in the fields of group cohomology, homological algebra and number theory, the Lyndon spectral sequence or Hochschild–Serre spectral sequence is a spectral sequence relating the group cohomology of a normal subgroup N and the quotient group G/N to the cohomology of the total group G. The spectral sequence is named after Roger Lyndon, Gerhard Hochschild, and Jean-Pierre Serre.

Let ${\displaystyle G}$ be a group and ${\displaystyle N}$ be a normal subgroup. The latter ensures that the quotient ${\displaystyle G/N}$ is a group, as well. Finally, let ${\displaystyle A}$ be a ${\displaystyle G}$-module. Then there is a spectral sequence of cohomological type

${\displaystyle H^p(G/N,H^q(N,A))⟹H^{p+q}(G,A)}$

and there is a spectral sequence of homological type

${\displaystyle H_p(G/N,H_q(N,A))⟹H_{p+q}(G,A)}$,

where the arrow '${\displaystyle ⟹}$' means convergence of spectral sequences.

The same statement holds if ${\displaystyle G}$ is a profinite group, ${\displaystyle N}$ is a closed normal subgroup and ${\displaystyle H^{\ast }}$ denotes the continuous cohomology.

The spectral sequence can be used to compute the homology of the Heisenberg group G with integral entries, i.e., matrices of the form

${\displaystyle \left(\begin{array}{ccc}1& a& c\\ 0& 1& b\\ 0& 0& 1\end{array}\right),a,b,c\in \mathbb{Z}.}$

This group is a central extension

${\displaystyle 0\to \mathbb{Z}\to G\to \mathbb{Z}\oplus \mathbb{Z}\to 0}$

with center ${\displaystyle \mathbb{Z}}$ corresponding to the subgroup with ${\displaystyle a=b=0}$. The spectral sequence for the group homology, together with the analysis of a differential in this spectral sequence, shows that^[1]

${\displaystyle H_i(G,\mathbb{Z})=\{\begin{array}{cc}\mathbb{Z}& i=0,3\\ \mathbb{Z}\oplus \mathbb{Z}& i=1,2\\ 0& i>3.\end{array}}$

For a group G, the wreath product is an extension

${\displaystyle 1\to G^p\to G\wr \mathbb{Z}/p\to \mathbb{Z}/p\to 1.}$

The resulting spectral sequence of group cohomology with coefficients in a field k,

${\displaystyle H^r(\mathbb{Z}/p,H^s(G^p,k))\Rightarrow H^{r+s}(G\wr \mathbb{Z}/p,k),}$

is known to degenerate at the ${\displaystyle E_2}$-page.^[2]

The associated five-term exact sequence is the usual inflation-restriction exact sequence:

${\displaystyle 0\to H^1(G/N,A^N)\to H^1(G,A)\to H^1(N,A{)}^{G/N}\to H^2(G/N,A^N)\to H^2(G,A).}$

The spectral sequence is an instance of the more general Grothendieck spectral sequence of the composition of two derived functors. Indeed, ${\displaystyle H^{\ast }(G,-)}$ is the derived functor of ${\displaystyle (-{)}^G}$ (i.e., taking G-invariants) and the composition of the functors ${\displaystyle (-{)}^N}$ and ${\displaystyle (-{)}^{G/N}}$ is exactly ${\displaystyle (-{)}^G}$.

A similar spectral sequence exists for group homology, as opposed to group cohomology, as well.^[3]

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