In mathematics, an alternating group is the group of even permutations of a finite set. The alternating group on a set of elements is called the alternating group of degree , or the alternating group on letters and denoted by or
For , the group A<sub>n</sub> is the commutator subgroup of the symmetric group S<sub>n</sub> with index 2 and has therefore n!/2 elements. It is the kernel of the signature group homomorphism explained under symmetric group.
The group A<sub>n</sub> is abelian if and only if and simple if and only if or . A<sub>5</sub> is the smallest non-abelian simple group, having order 60, and thus the smallest non-solvable group.
The group A<sub>4</sub> has the Klein four-group V as a proper normal subgroup, namely the identity and the double transpositions , that is the kernel of the surjection of A<sub>4</sub> onto . We have the exact sequence . In Galois theory, this map, or rather the corresponding map , corresponds to associating the Lagrange resolvent cubic to a quartic, which allows the quartic polynomial to be solved by radicals, as established by Lodovico Ferrari.
As in the symmetric group, any two elements of A<sub>n</sub> that are conjugate by an element of A<sub>n</sub> must have the same cycle shape. The converse is not necessarily true, however. If the cycle shape consists only of cycles of odd length with no two cycles the same length, where cycles of length one are included in the cycle type, then there are exactly two conjugacy classes for this cycle shape .
Examples:
As finite symmetric groups are the groups of all permutations of a set with finite elements, and the alternating groups are groups of even permutations, alternating groups are subgroups of finite symmetric groups.
For n âÂÂ¥ 3, A<sub>n</sub> is generated by 3-cycles, since 3-cycles can be obtained by combining pairs of transpositions. This generating set is often used to prove that A<sub>n</sub> is simple for .
For , except for , the automorphism group of A<sub>n</sub> is the symmetric group S<sub>n</sub>, with inner automorphism group A<sub>n</sub> and outer automorphism group Z<sub>2</sub>; the outer automorphism comes from conjugation by an odd permutation.
For and 2, the automorphism group is trivial. For the automorphism group is Z<sub>2</sub>, with trivial inner automorphism group and outer automorphism group Z<sub>2</sub>.
The outer automorphism group of A<sub>6</sub> is the Klein four-group , and is related to the outer automorphism of S<sub>6</sub>. The extra outer automorphism in A<sub>6</sub> swaps the 3-cycles (like (123)) with elements of shape 3<sup>2</sup> (like ).
There are some exceptional isomorphisms between some of the small alternating groups and small groups of Lie type, particularly projective special linear groups. These are:
More obviously, A<sub>3</sub> is isomorphic to the cyclic group Z<sub>3</sub>, and A<sub>0</sub>, A<sub>1</sub>, and A<sub>2</sub> are isomorphic to the trivial group (which is also for any q).
A<sub>5</sub> is the group of isometries of a dodecahedron in 3-space, so there is a representation .
In this picture the vertices of the polyhedra represent the elements of the group, with the center of the sphere representing the identity element. Each vertex represents a rotation about the axis pointing from the center to that vertex, by an angle equal to the distance from the origin, in radians. Vertices in the same polyhedron are in the same conjugacy class. Since the conjugacy class equation for A<sub>5</sub> is , we obtain four distinct (nontrivial) polyhedra.
The vertices of each polyhedron are in bijective correspondence with the elements of its conjugacy class, with the exception of the conjugacy class of (2,2)-cycles, which is represented by an icosidodecahedron on the outer surface, with its antipodal vertices identified with each other. The reason for this redundancy is that the corresponding rotations are by radians, and so can be represented by a vector of length in either of two directions. Thus the class of (2,2)-cycles contains 15 elements, while the icosidodecahedron has 30 vertices.
The two conjugacy classes of twelve 5-cycles in A<sub>5</sub> are represented by two icosahedra, of radii 2/5 and 4/5, respectively. The nontrivial outer automorphism in interchanges these two classes and the corresponding icosahedra.
It can be proved that the 15 puzzle, a famous example of the sliding puzzle, can be represented by the alternating group A<sub>15</sub>, because the combinations of the 15 puzzle can be generated by 3-cycles. In fact, any sliding puzzle with square tiles of equal size can be represented by A<sub>2kâÂÂ1</sub>.
A<sub>4</sub> is the smallest group demonstrating that the converse of Lagrange's theorem is not true in general: given a finite group G and a divisor d of , there does not necessarily exist a subgroup of G with order d: the group , of order 12, has no subgroup of order 6. A subgroup of three elements (generated by a cyclic rotation of three objects) with any distinct nontrivial element generates the whole group.
For all , A<sub>n</sub> has no nontrivial (that is, proper) normal subgroups. Thus, A<sub>n</sub> is a simple group for all . A<sub>5</sub> is the smallest non-solvable group.
The group homology of the alternating groups exhibits stabilization, as in stable homotopy theory: for sufficiently large n, it is constant. However, there are some low-dimensional exceptional homology. Note that the homology of the symmetric group exhibits similar stabilization, but without the low-dimensional exceptions (additional homology elements).
The first homology group coincides with abelianization, and (since A<sub>n</sub> is perfect, except for the cited exceptions) is thus:
This is easily seen directly, as follows. A<sub>n</sub> is generated by 3-cycles â so the only non-trivial abelianization maps are since order-3 elements must map to order-3 elements â and for all 3-cycles are conjugate, so they must map to the same element in the abelianization, since conjugation is trivial in abelian groups. Thus a 3-cycle like (123) must map to the same element as its inverse (321), but thus must map to the identity, as it must then have order dividing 2 and 3, so the abelianization is trivial.
For , A<sub>n</sub> is trivial, and thus has trivial abelianization. For A<sub>3</sub> and A<sub>4</sub> one can compute the abelianization directly, noting that the 3-cycles form two conjugacy classes (rather than all being conjugate) and there are non-trivial maps (in fact an isomorphism) and .
The Schur multipliers of the alternating groups A<sub>n</sub> (in the case where n is at least 5) 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. These were first computed in .