In the area of modern algebra known as group theory, the McLaughlin group McL is a sporadic simple group of order
27 ⋅ 36 ⋅ 53 ⋅ 7 ⋅ 11 = 898,128,000
≈ 9.
McL is one of the 26 sporadic groups and was discovered by as an index 2 subgroup of a rank 3 permutation group acting on the McLaughlin graph with vertices. It fixes a 2-2-3 triangle in the Leech lattice and thus is a subgroup of the Conway groups
Co0
Co2
Co3
McL has one conjugacy class of involution (element of order 2), whose centralizer is a maximal subgroup of type 2.A8. This has a center of order 2; the quotient modulo the center is isomorphic to the alternating group A8.
In the Conway group Co3, McL has the normalizer McL:2, which is maximal in Co3.
McL has 2 classes of maximal subgroups isomorphic to the Mathieu group M22. An outer automorphism interchanges the two classes of M22 groups. This outer automorphism is realized on McL embedded as a subgroup of Co3.
A convenient representation of M22 is in permutation matrices on the last 22 coordinates; it fixes a 2-2-3 triangle with vertices the origin and the type 2 points and '. The triangle's edge is type 3; it is fixed by a Co3. This M22 is the monomial, and a maximal, subgroup of a representation of McL.
(p. 207) shows that the subgroup McL is well-defined. In the Leech lattice, suppose a type 3 point v is fixed by an instance of
Co3
|McL| = |Co3|/552 = 898,128,000.
McL is the only sporadic group to admit irreducible representations of quaternionic type. It has 2 such representations, one of dimension 3520 and one of dimension 4752.
found the 12 conjugacy classes of maximal subgroups of McL as follows:
Traces of matrices in a standard 24-dimensional representation of McL are shown. [1] The names of conjugacy classes are taken from the Atlas of Finite Group Representations.[2]
Cycle structures in the rank 3 permutation representation, degree 275, of McL are shown.[3]
| Class | Centraliser order | No. elements | Trace | Cycle type | |
|---|---|---|---|---|---|
| 1A | 898,128,000 | 1 | 24 | ||
| 2A | 40,320 | 34 ⋅ 52 ⋅ 11 | 8 | 135, 2120 | |
| 3A | 29,160 | 24 ⋅ 52 ⋅ 7 ⋅ 11 | -3 | 15, 390 | |
| 3B | 972 | 23 ⋅ 3 ⋅ 53 ⋅ 7 ⋅ 11 | 6 | 114, 387 | |
| 4A | 96 | 22 ⋅ 35 ⋅ 53 ⋅ 7 ⋅ 11 | 4 | 17, 214, 460 | |
| 5A | 750 | 26 ⋅ 35 ⋅ ⋅ 7 ⋅ 11 | -1 | 555 | |
| 5B | 25 | 27 ⋅ 36 ⋅ 5 ⋅ 7 ⋅ 11 | 4 | 15, 554 | |
| 6A | 360 | 24 ⋅ 34 ⋅ 52 ⋅ 7 ⋅ 11 | 5 | 15, 310, 640 | |
| 6B | 36 | 25 ⋅ 34 ⋅ 53 ⋅ 7 ⋅ 11 | 2 | 12, 26, 311, 638 | |
| 7A | 14 | 26 ⋅ 36 ⋅ 53 ⋅ 11 | 3 | 12, 739 | power equivalent |
| 7B | 14 | 26 ⋅ 36 ⋅ 53 ⋅ 11 | 3 | 12, 739 | |
| 8A | 8 | 24 ⋅ 36 ⋅ 53 ⋅ 7 ⋅ 11 | 2 | 1, 23, 47, 830 | |
| 9A | 27 | 27 ⋅ 33 ⋅ 53 ⋅ 7 ⋅ 11 | 3 | 12, 3, 930 | power equivalent |
| 9B | 27 | 27 ⋅ 33 ⋅ 53 ⋅ 7 ⋅ 11 | 3 | 12, 3, 930 | |
| 10A | 10 | 26 ⋅ 35 ⋅ 53 ⋅ 7 ⋅ 11 | 3 | 57, 1024 | |
| 11A | 11 | 27 ⋅ 36 ⋅ 53 ⋅ 7 | 2 | 1125 | power equivalent |
| 11B | 11 | 27 ⋅ 36 ⋅ 53 ⋅ 7 | 2 | 1125 | |
| 12A | 12 | 25 ⋅ 35 ⋅ 53 ⋅ 7 ⋅ 11 | 1 | 1, 22, 32, 64, 1220 | |
| 14A | 14 | 26 ⋅ 36 ⋅ 53 ⋅ 11 | 1 | 2, 75, 1417 | power equivalent |
| 14B | 14 | 26 ⋅ 36 ⋅ 53 ⋅ 11 | 1 | 2, 75, 1417 | |
| 15A | 30 | 26 ⋅ 35 ⋅ 52 ⋅ 7 ⋅ 11 | 2 | 5, 1518 | power equivalent |
| 15B | 30 | 26 ⋅ 35 ⋅ 52 ⋅ 7 ⋅ 11 | 2 | 5, 1518 | |
| 30A | 30 | 26 ⋅ 35 ⋅ 52 ⋅ 7 ⋅ 11 | 0 | 5, 152, 308 | power equivalent |
| 30B | 30 | 26 ⋅ 35 ⋅ 52 ⋅ 7 ⋅ 11 | 0 | 5, 152, 308 |
Conway and Norton suggested in their 1979 paper that monstrous moonshine is not limited to the monster. Larissa Queen and others subsequently found that one can construct the expansions of many Hauptmoduln from simple combinations of dimensions of sporadic groups. For the Conway groups, the relevant McKay–Thompson series is
T2A(\tau)
T4A(\tau)