Lyndon–Hochschild–Serre spectral sequence: Difference between revisions

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			{{Short description\|Topic in mathematics}}
⚫	In ], especially in the fields of ], ] and ] the '''Lyndon spectral sequence''' or '''~~Hochschild-Serre~~ spectral sequence''' is a ] relating the group cohomology of a normal subgroup ''N'' and the quotient group ''G''/''N'' to the cohomology of the total group ''G''. In ~~fact,~~ ~~the~~ ~~associated~~ ] ~~is the usual~~ ].

		⚫	In ], especially in the fields of ], ] and ], the '''Lyndon spectral sequence''' or '''Hochschild–Serre spectral sequence''' is a ] relating the ] of a normal subgroup ''N'' and the quotient group ''G''/''N'' to the ] of the total group ''G''. The spectral sequence is named after ], ], and ].
	The precise statement is as follows:

			==Statement==
	Let ''G'' be a ~~finite~~ ], ''N'' be a ]. The latter ensures that the quotient ''G''/''N'' is a group, as well. Finally, let ''A'' be a ''G''-module. Then there is a spectral sequence:		Let <math>G</math> be a ] and <math>N</math> be a ]. The latter ensures that the ] <math>G/N</math> is a group, as well. Finally, let <math>A</math> be a ]. Then there is a ] of cohomological type

	: <math> H^p(G/N, H^q(N,A)) \~~implies~~ H^{p+q}(G,A)~~.\,~~ </math>		:<math>H^p(G/N,H^q(N,A)) \Longrightarrow H^{p+q}(G,A)</math>

			and there is a ]
⚫	The same statement holds if ''G'' is a ] ~~and ''~~N'' is a ''closed'' normal subgroup.

			:<math>H_p(G/N,H_q(N,A)) \Longrightarrow H_{p+q}(G,A)</math>,
⚫	The spectral sequence is an instance of the more general ] of the composition of two derived functors. Indeed, ~~''H''~~<~~sup>&lowast;</sup~~>(''G'', -) is the ] of (~~−~~)~~<sup>''~~G''</~~sup~~> (i.e. taking ''G''-invariants) and the composition of the functors (~~−~~)~~<sup>''~~N''</~~sup~~> and (~~−~~)~~<sup>''~~G/N''</~~sup~~> is exactly (~~−~~)~~<sup>''~~G''</~~sup~~>.
			where the arrow '<math>\Longrightarrow</math>' means ].

		⚫	The same statement holds if <math>G</math> is a ], <math>N</math> is a ''closed'' normal subgroup and <math>H^*</math> denotes the continuous cohomology.
	==Reference==
⚫	* {{Citation \| last1=Lyndon \| first1=Roger B. \| title=The cohomology theory of group extensions \| year=1948 \| journal=] \| issn=0012-7094 \| volume=15 \| issue=1 \| pages=271–292}}
⚫	* {{Citation \| last1=Hochschild \| first1=G. \| last2=Serre \| first2=Jean-Pierre \| author2-link=~~en:~~Jean-Pierre Serre \| title=Cohomology of group extensions \| id=~~{{MathSciNet \| id =~~ 0052438}} \| year=1953 \| journal=Transactions of the American Mathematical Society \| issn=0002-9947 \| volume=74 \| pages=110–134}}
	* {{Citation \| last1=Neukirch \| first1=Jürgen \| last2=Schmidt \| first2=Alexander \| last3=Wingberg \| first3=Kay \| title=Cohomology of Number Fields \| publisher=] \| location=Berlin, New York \| series=Grundlehren der Mathematischen Wissenschaften \| isbn=978-3-540-66671-4 \| id={{MathSciNet \| id = 1737196}} \| year=2000 \| volume=323}}

			== Examples ==
⚫	] ]
			=== Homology of the Heisenberg group ===

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

			:<math>\left ( \begin{array}{ccc} 1 & a & c \\ 0 & 1 & b \\ 0 & 0 & 1 \end{array} \right ), \ a, b, c \in \Z.</math>

			This group is a ]

			:<math>0 \to \Z \to G \to \Z \oplus \Z \to 0</math>

			with ] <math>\Z</math> corresponding to the subgroup with <math>a=b=0</math>. The spectral sequence for the group homology, together with the analysis of a differential in this spectral sequence, shows that<ref>{{cite book\|first=Kevin\|last= Knudson\| title=Homology of Linear Groups\|series=Progress in Mathematics\|volume= 193\| publisher= ]\|location=Basel\|year=2001\| isbn = 3-7643-6415-7\|doi=10.1007/978-3-0348-8338-2\|mr=1807154}} Example A.2.4</ref>

			:<math>H_i (G, \Z) = \left \{ \begin{array}{cc} \Z & i=0, 3 \\ \Z \oplus \Z & i=1,2 \\ 0 & i>3. \end{array} \right. </math>

			=== Cohomology of wreath products ===

			For a group ''G'', the ] is an extension

			:<math>1 \to G^p \to G \wr \Z / p \to \Z / p \to 1.</math>

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

			:<math>H^r(\Z/p, H^s(G^p, k)) \Rightarrow H^{r+s}(G \wr \Z/p, k),</math>

			is known to degenerate at the <math>E_2</math>-page.<ref>{{citation\|title=Decomposition Theorem for Homology Groups of Symmetric Groups\|
			first=Minoru\|last= Nakaoka\|journal=] \|series=Second Series\|volume=71\|issue=1\|year=1960\|pages=16–42\|jstor=1969878\|doi=10.2307/1969878}}, for a brief summary see section 2 of {{citation\|last1=Carlson\|first1= Jon F.\|last2=Henn\|first2= Hans-Werner\| title=Depth and the cohomology of wreath products\|journal=] \|volume=87\|issue=2\|year=1995\|pages=145–151\|doi= 10.1007/BF02570466\|citeseerx= 10.1.1.540.1310\|s2cid= 27212941}}</ref>

			==Properties==
			The associated ] is the usual ]:

			:<math>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).</math>

			==Generalizations==
		⚫	The spectral sequence is an instance of the more general ] of the composition of two derived functors. Indeed, <math>H^{*}(G,-)</math> is the ] of <math>(-)^G</math> (i.e., taking ''G''-invariants) and the composition of the functors <math>(-)^N</math> and <math>(-)^{G/N}</math> is exactly <math>(-)^G</math>.

			A similar spectral sequence exists for group homology, as opposed to group cohomology, as well.<ref>{{Citation \| last1=McCleary \| first1=John \| title=A User's Guide to Spectral Sequences \| publisher=] \| edition=2nd \| series=Cambridge Studies in Advanced Mathematics \| isbn=978-0-521-56759-6 \|mr=1793722 \| year=2001 \| volume=58}}, Theorem 8<sup>bis</sup>.12</ref>

			==References==
			<references />
		⚫	* {{Citation \| last1=Lyndon \| first1=Roger C. \| authorlink = Roger Lyndon \| title=The cohomology theory of group extensions \| year=1948 \| journal=] \| issn=0012-7094 \| volume=15 \| issue=1 \| pages=271–292 \| doi=10.1215/S0012-7094-48-01528-2}} (paywalled)
		⚫	* {{Citation \| last1=Hochschild \| first1=Gerhard \| author1-link = Gerhard Hochschild \| last2=Serre \| first2=Jean-Pierre \| author2-link = Jean-Pierre Serre \| title=Cohomology of group extensions \|mr=0052438 \| year=1953 \| journal=] \| issn=0002-9947 \| volume=74 \| pages=110–134 \| doi=10.2307/1990851 \| issue=1 \| jstor=1990851\| doi-access=free }}
			* {{Neukirch et al. CNF}}

			{{DEFAULTSORT:Lyndon-Hochschild-Serre spectral sequence}}
		⚫	]
			]

Latest revision as of 16:44, 3 June 2024

Topic in mathematics

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.

Statement

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

H^{p}(G/N,H^{q}(N,A))\Longrightarrow H^{p+q}(G,A)

and there is a spectral sequence of homological type

H_{p}(G/N,H_{q}(N,A))\Longrightarrow H_{p+q}(G,A)

where the arrow ' $\Longrightarrow$ ' means convergence of spectral sequences.

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

Examples

Homology of the Heisenberg group

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

\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

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

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

H_{i}(G,\mathbb {Z} )=\left\{{\begin{array}{cc}\mathbb {Z} &i=0,3\\\mathbb {Z} \oplus \mathbb {Z} &i=1,2\\0&i>3.\end{array}}\right.

Cohomology of wreath products

For a group G, the wreath product is an extension

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,

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 $E_{2}$ -page.

Properties

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

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).

Generalizations

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

A similar spectral sequence exists for group homology, as opposed to group cohomology, as well.

References

Knudson, Kevin (2001). Homology of Linear Groups. Progress in Mathematics. Vol. 193. Basel: Birkhäuser Verlag. doi:10.1007/978-3-0348-8338-2. ISBN 3-7643-6415-7. MR 1807154. Example A.2.4
Nakaoka, Minoru (1960), "Decomposition Theorem for Homology Groups of Symmetric Groups", Annals of Mathematics, Second Series, 71 (1): 16–42, doi:10.2307/1969878, JSTOR 1969878, for a brief summary see section 2 of Carlson, Jon F.; Henn, Hans-Werner (1995), "Depth and the cohomology of wreath products", Manuscripta Mathematica, 87 (2): 145–151, CiteSeerX 10.1.1.540.1310, doi:10.1007/BF02570466, S2CID 27212941
McCleary, John (2001), A User's Guide to Spectral Sequences, Cambridge Studies in Advanced Mathematics, vol. 58 (2nd ed.), Cambridge University Press, ISBN 978-0-521-56759-6, MR 1793722, Theorem 8.12

Lyndon, Roger C. (1948), "The cohomology theory of group extensions", Duke Mathematical Journal, 15 (1): 271–292, doi:10.1215/S0012-7094-48-01528-2, ISSN 0012-7094 (paywalled)
Hochschild, Gerhard; Serre, Jean-Pierre (1953), "Cohomology of group extensions", Transactions of the American Mathematical Society, 74 (1): 110–134, doi:10.2307/1990851, ISSN 0002-9947, JSTOR 1990851, MR 0052438
Neukirch, Jürgen; Schmidt, Alexander; Wingberg, Kay (2000), Cohomology of Number Fields, Grundlehren der Mathematischen Wissenschaften, vol. 323, Berlin: Springer-Verlag, ISBN 978-3-540-66671-4, MR 1737196, Zbl 0948.11001

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