All perfect alternating groups have perfect double covers. In most cases this is the
universal central extension. The two exceptions are A6 (whose perfect triple cover is the Valentiner group) and A7, whose universal central extensions have centers of order 6.
Representations
The alternating group A6 acts on the complex projective plane, and
Gerbaldi (1898) showed that the group acts on the 6 conics of
Gerbaldi's theorem. This gives a homomorphism to PGL3(C), and the lift of this to the triple cover GL3(C) is the Valentiner group. This embedding can be defined over the field generated by the 15th roots of unity.
The product of the Valentiner group with a group of order 2 is a 3-dimensional
complex reflection group of order 2160 generated by 45 complex reflections of order 2. The invariants form a
polynomial algebra with generators of degrees 6, 12, and 30.
The Valentiner group has complex irreducible faithful
group representations of dimension 3, 3, 3, 3, 6, 6, 9, 9, 15, 15.
The Valentiner group can be represented as the monomial symmetries of the
hexacode, the 3-dimensional subspace of F6 4 spanned by (001111), (111100), and (0101ωω), where the elements of the finite field F4 are 0, 1, ω, ω.
The group PGL3(F4) acts on the 2-dimensional projective plane over F4 and acts transitively on its
hyperovals (sets of 6 points such that no three are on a line). The subgroup fixing a hyperoval is a copy of the alternating group A6. The lift of this to the triple cover GL3(F4) of PGL3(F4) is the Valentiner group.
All perfect alternating groups have perfect double covers. In most cases this is the
universal central extension. The two exceptions are A6 (whose perfect triple cover is the Valentiner group) and A7, whose universal central extensions have centers of order 6.
Representations
The alternating group A6 acts on the complex projective plane, and
Gerbaldi (1898) showed that the group acts on the 6 conics of
Gerbaldi's theorem. This gives a homomorphism to PGL3(C), and the lift of this to the triple cover GL3(C) is the Valentiner group. This embedding can be defined over the field generated by the 15th roots of unity.
The product of the Valentiner group with a group of order 2 is a 3-dimensional
complex reflection group of order 2160 generated by 45 complex reflections of order 2. The invariants form a
polynomial algebra with generators of degrees 6, 12, and 30.
The Valentiner group has complex irreducible faithful
group representations of dimension 3, 3, 3, 3, 6, 6, 9, 9, 15, 15.
The Valentiner group can be represented as the monomial symmetries of the
hexacode, the 3-dimensional subspace of F6 4 spanned by (001111), (111100), and (0101ωω), where the elements of the finite field F4 are 0, 1, ω, ω.
The group PGL3(F4) acts on the 2-dimensional projective plane over F4 and acts transitively on its
hyperovals (sets of 6 points such that no three are on a line). The subgroup fixing a hyperoval is a copy of the alternating group A6. The lift of this to the triple cover GL3(F4) of PGL3(F4) is the Valentiner group.