In the area of modern algebra known as group theory, the Conway group Co<sub>2</sub> is a sporadic simple group of order
Co<sub>2</sub> is one of the 26 sporadic groups and was discovered by as the group of automorphisms of the Leech lattice ÃÂ fixing a lattice vector of type 2. It is thus a subgroup of Co<sub>0</sub>. It is isomorphic to a subgroup of Co<sub>1</sub>. The direct product 2ÃÂCo<sub>2</sub> is maximal in Co<sub>0</sub>.
The Schur multiplier and the outer automorphism group are both trivial.
Co<sub>2</sub> acts as a rank 3 permutation group on 2300 points. These points can be identified with planar hexagons in the Leech lattice having 6 type 2 vertices.
Co<sub>2</sub> acts on the 23-dimensional even integral lattice with no roots of determinant 4, given as a sublattice of the Leech lattice orthogonal to a norm 4 vector. Over the field with 2 elements it has a 22-dimensional faithful representation; this is the smallest faithful representation over any field.
showed that if a finite group has an absolutely irreducible faithful rational representation of dimension 23 and has no subgroups of index 23 or 24 then it is contained in either Z/2Z ÃÂ Co<sub>2</sub> or Z/2Z ÃÂ Co<sub>3</sub>.
The Mathieu group M<sub>23</sub> is isomorphic to a maximal subgroup of Co<sub>2</sub> and one representation, in permutation matrices, fixes the type 2 vector u = (-3,1<sup>23</sup>). A block sum ö of the involution ÷ =
and 5 copies of -÷ also fixes the same vector. Hence Co<sub>2</sub> has a convenient matrix representation inside the standard representation of Co<sub>0</sub>. The trace of ö is -8, while the involutions in M<sub>23</sub> have trace 8.
A 24-dimensional block sum of ÷ and -÷ is in Co<sub>0</sub> if and only if the number of copies of ÷ is odd.
Another representation fixes the vector v = (4,-4,0<sup>22</sup>). A monomial and maximal subgroup includes a representation of M<sub>22</sub>:2, where any ñ interchanging the first 2 co-ordinates restores v by then negating the vector. Also included are diagonal involutions corresponding to octads (trace 8), 16-sets (trace -8), and dodecads (trace 0). It can be shown that Co<sub>2</sub> has just 3 conjugacy classes of involutions. ÷ leaves (4,-4,0,0) unchanged; the block sum ö provides a non-monomial generator completing this representation of Co<sub>2</sub>.
There is an alternate way to construct the stabilizer of v. Now u and u+v = (1,-3,1<sup>22</sup>) are vertices of a 2-2-2 triangle (vide infra). Then u, u+v, v, and their negatives form a coplanar hexagon fixed by ö and M<sub>22</sub>; these generate a group Fi<sub>21</sub> â U<sub>6</sub>(2). ñ (vide supra) extends this to Fi<sub>21</sub>:2, which is maximal in Co<sub>2</sub>. Lastly, Co<sub>0</sub> is transitive on type 2 points, so that a 23-cycle fixing u has a conjugate fixing v, and the generation is completed.
Some maximal subgroups fix or reflect 2-dimensional sublattices of the Leech lattice. It is usual to define these planes by h-k-l triangles: triangles including the origin as a vertex, with edges (differences of vertices) being vectors of types h, k, and l.
found the 11 conjugacy classes of maximal subgroups of Co<sub>2</sub> as follows:
Traces of matrices in a standard 24-dimensional representation of Co<sub>2</sub> are shown. The names of conjugacy classes are taken from the Atlas of Finite Group Representations.
Centralizers of unknown structure are indicated with brackets.