Double cover of symmetric group: Difference between revisions

Revision as of 16:00, 1 November 2011

Definition

The term double cover of symmetric group is used for a stem extension where the base normal subgroup is cyclic group:Z2 and the quotient group is an symmetric group of finite degree.

A double cover exists for the symmetric group $S_{n}$ only when $n \geq 4$ . Further, for each $n$ , there are two possibilities for the double cover, the "+" type and the "-" type.

If we consider the group cohomology of symmetric groups and in particular the second cohomology group for trivial group action $H^{2} (S_{n}; Z_{2})$ for $n \geq 4$ , this second cohomology group is isomorphic to the Klein four-group, and two of the three nontrivial elements of the group correspond to these double covers. The third nontrivial element corresponds to a group extension where the alternating group in the quotient is kept intact and the odd permutations square to the non-identity central element.

In all cases, both double covers are Schur covering groups for the corresponding symmetric group, because the Schur multiplier is precisely cyclic group:Z2.

Presentation for "-" type double cover

This group, denoted $2 \cdot S_{n}^{-}$ , has a presentation with generating set of size $n$ given by $z, s_{1}, s_{2}, \dots, s_{n - 1}$ . The idea is that under the surjective map to $S_{n}$ , $z$ maps to the identity and the relations collapse to the Coxeter presentation of $S_{n}$ . The subgroup $⟨ z ⟩$ is the base cyclic group:Z2. The relations (here $e$ denotes the identity element):

Relation	Condition on subscripts	Number of such relations	What it descends to when we quotient to $S_{n}$
$z^{2} = e$	no subscripts	1	$e = e$ , i.e., a vacuous relation
$s_{i}^{2} = z$	$1 \leq i \leq n - 1$	$n - 1$	$s_{i}^{2} = e$
$s_{i + 1} s_{i} s_{i + 1} = s_{i} s_{i + 1} s_{i} z$	$1 \leq i \leq n - 2$	$n - 2$	$s_{i + 1} s_{i} s_{i + 1} = s_{i} s_{i + 1} s_{i}$
$s_{j} s_{i} = s_{i} s_{j} z$	$1 \leq i < j \leq n - 1$ and $\| i - j \| \geq 2$	$(n - 2) (n - 3) / 2$	$s_{j} s_{i} = s_{i} s_{j}$
Total (--)	--	$(n^{2} - n + 2) / 2$	--

Presentation for "+" type double cover

This group, denoted $2 \cdot S_{n}^{-}$ , has a presentation with generating set of size $n$ given by $z, s_{1}, s_{2}, \dots, s_{n - 1}$ . The idea is that under the surjective map to $S_{n}$ , $z$ maps to the identity and the relations collapse to the Coxeter presentation of $S_{n}$ . The subgroup $⟨ z ⟩$ is the base cyclic group:Z2. The relations (here $e$ denotes the identity element):

Relation	Condition on subscripts	Number of such relations	What it descends to when we quotient to $S_{n}$
$z^{2} = e$	no subscripts	1	$e = e$ , i.e., a vacuous relation
$s_{i} z = z s_{i}$	$1 \leq i \leq n - 1$	$n - 1$	$s_{i} = s_{i}$ , i.e., a vacuous relation
$s_{i}^{2} = e$	$1 \leq i \leq n - 1$	$n - 1$	$s_{i}^{2} = e$
$s_{i + 1} s_{i} s_{i + 1} = s_{i} s_{i + 1} s_{i}$	$1 \leq i \leq n - 2$	$n - 2$	$s_{i + 1} s_{i} s_{i + 1} = s_{i} s_{i + 1} s_{i}$
$s_{j} s_{i} = s_{i} s_{j} z$	$1 \leq i < j \leq n - 1$ and $\| i - j \| \geq 2$	$(n - 2) (n - 3) / 2$	$s_{j} s_{i} = s_{i} s_{j}$
Total (--)	--	$(n^{2} + n) / 2$	--

Particular cases

$n$	order of symmetric group $S_{n}$	order of double cover of symmetric group = $2 (n!)$	symmetric group $S_{n}$	$2 \cdot S_{n}^{-}$ (double cover of "-" type)	$2 \cdot S_{n}^{+}$ (double cover of "+" type)	Cohomology information	Cohomology group information
4	24	48	symmetric group:S4	binary octahedral group	general linear group:GL(2,3)	group cohomology of symmetric group:S4	second cohomology group for trivial group action of S4 on Z2
5	120	240	symmetric group:S5	?	?	group cohomology of symmetric group:S5	second cohomology group for trivial group action of S5 on Z2

@@ Line 35: / Line 35: @@
 |-
 | <math>\! z^2 = e</math> || no subscripts || 1 || <math>e = e</math>, i.e., a vacuous relation
+|-
+| <math>\! s_iz = zs_i</math> || <math>1 \le i \le n- 1</math> || <math>n - 1</math> || <math>s_i = s_i</math>, i.e., a vacuous relation
 |-
 | <math>\! s_i^2 = e</math> || <math>1 \le i \le n - 1</math> || <math>n - 1</math> || <math>s_i^2 = e</math>
@@ Line 42: / Line 44: @@
 | <math>\! s_js_i = s_is_jz</math> || <math>1 \le i < j \le n - 1</math> and <math>|i - j| \ge 2</math> || <math>(n - 2)(n - 3)/2</math> || <math>s_js_i = s_is_j</math>
 |-
-| Total (--) || -- || <math>(n^2 - n + 2)/2</math> || --
+| Total (--) || -- || <math>(n^2 + n)/2</math> || --
 |}