Covering Groups Of The Alternating And Symmetric Groups

In the mathematical area of group theory, the covering groups of the alternating and symmetric groups are groups that are used to understand the projective representations of the alternating and symmetric groups. The covering groups were classified in : for , the covering groups are 2-fold covers except for the alternating groups of degree 6 and 7 where the covers are 6-fold.

For example the binary icosahedral group covers the icosahedral group, an alternating group of degree 5, and the binary tetrahedral group covers the tetrahedral group, an alternating group of degree 4.

Definition and classification

A group homomorphism from ''D'' to ''G'' is said to be a Schur cover of the finite group ''G'' if:
# the kernel is contained both in the center and the commutator subgroup of ''D'', and
# amongst all such homomorphisms, this ''D'' has maximal size.
The Schur multiplier of ''G'' is the kernel of any Schur cover and has many interpretations. When the homomorphism is understood, the group ''D'' is often called the Schur cover or Darstellungsgruppe.

The Schur covers of the symmetric and alternating groups were classified in . The symmetric group of degree ''n'' ≥ 4 has
Schur covers of order 2⋅''n''! There are two isomorphism classes if ''n'' ≠ 6 and one isomorphism class if ''n'' = 6.
The alternating group of degree ''n'' has one isomorphism class of Schur cover, which has order ''n''! except when ''n'' is 6 or 7, in which case the Schur cover has order 3⋅''n''!.

Finite presentations

Schur covers can be described using finite presentations. The symmetric group ''S''_''n'' has a presentation on ''n''−1 generators ''t''_''i'' for ''i'' = 1, 2, ..., n−1 and relations
:''t''_''i''''t''_''i'' = 1, for 1 ≤ ''i'' ≤ ''n''−1
:''t''_''i''+1''t''_''i''''t''_''i''+1 = ''t''_''i''''t''_''i''+1''t''_''i'', for 1 ≤ ''i'' ≤ ''n''−2
:''t''_''j''''t''_''i'' = ''t''_''i''''t''_''j'', for 1 ≤ ''i'' < ''i''+2 ≤ ''j'' ≤ ''n''−1.

These relations can be used to describe two non-isomorphic covers of the symmetric group. One covering group $2\cdot S_n^-$ has generators ''z'', ''t''₁, ..., ''t''_''n''−1 and relations:
:''zz'' = 1
:''t''_''i''''t''_''i'' = ''z'', for 1 ≤ ''i'' ≤ ''n''−1
:''t''_''i''+1''t''_''i''''t''_''i''+1 = ''t''_''i''''t''_''i''+1''t''_''i'', for 1 ≤ ''i'' ≤ ''n''−2
:''t''_''j''''t''_''i'' = ''t''_''i''''t''_''j''''z'', for 1 ≤ ''i'' < ''i''+2 ≤ ''j'' ≤ ''n''−1.
The same group $2\cdot S_n^-$ can be given the following presentation using the generators ''z'' and ''s''_''i'' given by ''t''_''i'' or ''t''_''i''''z'' according as ''i'' is odd or even:
:''zz'' = 1
:''s''_''i''''s''_''i'' = ''z'', for 1 ≤ ''i'' ≤ ''n''−1
:''s''_''i''+1''s''_''i''''s''_''i''+1 = ''s''_''i''''s''_''i''+1''s''_''i''''z'', for 1 ≤ ''i'' ≤ ''n''−2
:''s''_''j''''s''_''i'' = ''s''_''i''''s''_''j''''z'', for 1 ≤ ''i'' < ''i''+2 ≤ ''j'' ≤ ''n''−1.

The other covering group $2\cdot S_n^+$ has generators ''z'', ''t''₁, ..., ''t''_''n''−1 and relations:
:''zz'' = 1, ''zt''_''i'' = ''t''_''i''''z'', for 1 ≤ ''i'' ≤ ''n''−1
:''t''_''i''''t''_''i'' = 1, for 1 ≤ ''i'' ≤ ''n''−1
:''t''_''i''+1''t''_''i''''t''_''i''+1 = ''t''_''i''''t''_''i''+1''t''_''i''''z'', for 1 ≤ ''i'' ≤ ''n''−2
:''t''_''j''''t''_''i'' = ''t''_''i''''t''_''j''''z'', for 1 ≤ ''i'' < ''i''+2 ≤ ''j'' ≤ ''n''−1.
The same group $2\cdot S_n^+$ can be given the following presentation using the generators ''z'' and ''s''_''i'' given by ''t''_''i'' or ''t''_''i''''z'' according as ''i'' is odd or even:
:''zz'' = 1, ''zs''_''i'' = ''s''_''i''''z'', for 1 ≤ ''i'' ≤ ''n''−1
:''s''_''i''''s''_''i'' = 1, for 1 ≤ ''i'' ≤ ''n''−1
:''s''_''i''+1''s''_''i''''s''_''i''+1 = ''s''_''i''''s''_''i''+1''s''_''i'', for 1 ≤ ''i'' ≤ ''n''−2
:''s''_''j''''s''_''i'' = ''s''_''i''''s''_''j''''z'', for 1 ≤ ''i'' < ''i''+2 ≤ ''j'' ≤ ''n''−1.

Sometimes all of the relations of the symmetric group are expressed as (''t''_''i''''t''_''j'')^''m''_''ij'' = 1, where ''m''_''ij'' are non-negative integers, namely ''m''_''ii'' = 1, ''m''_{''i'',''i''+1} = 3, and ''m''_''ij'' = 2, for 1 ≤ ''i'' < ''i''+2 ≤ ''j'' ≤ ''n''−1. The presentation of $2\cdot S_n^-$ becomes particularly simple in this form: (''t''_''i''''t''_''j'')^''m''_''ij'' = ''z'', and ''zz'' = 1. The group $2\cdot S_n^+$ has the nice property that its generators all have order 2.

Projective representations

Covering groups were introduced by Issai Schur to classify projective representations of groups. A (complex) ''linear'' representation of a group ''G'' is a group homomorphism ''G'' → GL(''n'',''C'') from the group ''G'' to a general linear group, while a ''projective'' representation is a homomorphism ''G'' → PGL(''n'',''C'') from ''G'' to a projective linear group. Projective representations of ''G'' correspond naturally to linear representations of the covering group of ''G''.

The projective representations of alternating and symmetric groups are the subject of the book .

Integral homology

Covering groups correspond to the second group homology group, H₂(''G'',Z), also known as the Schur multiplier. The Schur multipliers of the alternating groups ''A''_''n'' (in the case where ''n'' is at least 4) are the cyclic groups of order 2, except in the case where ''n'' is either 6 or 7, in which case there is also a triple cover. In these cases, then, the Schur multiplier is the cyclic group of order 6, and the covering group is a 6-fold cover.

:H₂(''A''_''n'',Z) = 0 for ''n'' ≤ 3
:H₂(''A''_''n'',Z) = Z/2Z for ''n'' = 4, 5
:H₂(''A''_''n'',Z) = Z/6Z for ''n'' = 6, 7
:H₂(''A''_''n'',Z) = Z/2Z for ''n'' ≥ 8

For the symmetric group, the Schur multiplier vanishes for n ≤ 3, and is the cyclic group of order 2 for n ≥ 4:
:H₂(''S''_''n'',Z) = 0 for ''n'' ≤ 3
:H₂(''S''_''n'',Z) = Z/2Z for ''n'' ≥ 4

Construction of double covers

The double covers can be constructed as spin (respectively, pin) covers of faithful, irreducible, linear representations of ''A''_''n'' and ''S''_''n''. These spin representations exist for all ''n,'' but are the covering groups only for n≥4 (n≠6,7 for ''A''_''n''). For ''n''≤3, ''S''_''n'' and ''A''_''n'' are their own Schur covers.

Explicitly, ''S''_''n'' acts on the ''n''-dimensional space R^''n'' by permuting coordinates (in matrices, as permutation matrices). This has a 1-dimensional trivial subrepresentation corresponding to vectors with all coordinates equal, and the complementary (''n''−1)-dimensional subrepresentation (of vectors whose coordinates sum to 0) is irreducible for n≥4. Geometrically, this is the symmetries of the (''n''−1)-simplex, and algebraically, it yields maps $A_n \hookrightarrow \operatorname(n-1)$ and $S_n \hookrightarrow \operatorname(n-1)$ expressing these as discrete subgroups (point groups). The special orthogonal group has a 2-fold cover by the spin group $\operatorname(n) \to \operatorname(n),$ and restricting this cover to $A_n$ and taking the preimage yields a 2-fold cover $2 \cdot A_n \to A_n.$ A similar construction with a pin group yields the 2-fold cover of the symmetric group: $\operatorname_\pm(n) \to \operatorname(n).$ As there are two pin groups, there are two distinct 2-fold covers of the symmetric group, 2⋅''S''_''n''^±, also called $\tilde S_n$ and $\hat S_n$.

Construction of triple cover for ''n'' = 6, 7

The triple covering of $A_6,$ denoted $3\cdot A_6,$ and the corresponding triple cover of $S_6,$ denoted $3\cdot S_6,$ can be constructed as symmetries of a certain set of vectors in a complex 6-space. While the exceptional triple covers of ''A''₆ and ''A''₇ extend to extensions of ''S''₆ and ''S''₇, these extensions are not central and so do not form Schur covers.

This construction is important in the study of the sporadic groups, and in much of the exceptional behavior of small classical and exceptional groups, including: construction of the Mathieu group M₂₄, the exceptional covers of the projective unitary group $U_4(3)$ and the projective special linear group $L_3(4),$ and the exceptional double cover of the group of Lie type $G_2(4).$.

Exceptional isomorphisms

For low dimensions there are exceptional isomorphisms with the map from a special linear group over a finite field to the projective special linear group.

For ''n'' = 3, the symmetric group is SL(2,2) ≅ PSL(2,2) and is its own Schur cover.

For ''n'' = 4, the Schur cover of the alternating group is given by SL(2,3) → PSL(2,3) ≅ ''A''₄, which can also be thought of as the binary tetrahedral group covering the tetrahedral group. Similarly, GL(2,3) → PGL(2,3) ≅ ''S''₄ is a Schur cover, but there is a second non-isomorphic Schur cover of ''S''₄ contained in GL(2,9) – note that 9=3² so this is extension of scalars of GL(2,3). In terms of the above presentations, GL(2,3) ≅ ''Ŝ''₄