Higman–Sims group
In the area of modern algebra known as group theory, the Higman–Sims group HS is a sporadic simple group of order
- 29⋅32⋅53⋅7⋅11 = 44352000
- ≈ 4×107.
Algebraic structure → Group theory Group theory |
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The Schur multiplier has order 2, the outer automorphism group has order 2, and the group 2.HS.2 appears as an involution centralizer in the Harada–Norton group.
History
HS is one of the 26 sporadic groups and was found by Donald G. Higman and Charles C. Sims (1968). They were attending a presentation by Marshall Hall on the Hall–Janko group J2. It happens that J2 acts as a permutation group on the Hall–Janko graph of 100 points, the stabilizer of one point being a subgroup with two other orbits of lengths 36 and 63. Inspired by this they decided to check for other rank 3 permutation groups on 100 points. They soon focused on a possible one containing the Mathieu group M22, which has permutation representations on 22 and 77 points. (The latter representation arises because the M22 Steiner system has 77 blocks.) By putting together these two representations, they found HS, with a one-point stabilizer isomorphic to M22.
HS is the simple subgroup of index two in the group of automorphisms of the Higman–Sims graph. The Higman–Sims graph has 100 nodes, so the Higman–Sims group HS is a transitive group of permutations of a 100 element set.
Graham Higman (1969) independently discovered the group as a doubly transitive permutation group acting on a certain 'geometry' on 176 points.
Construction
GAP code to build the Higman-Sims group is presented as an example in the GAP documentation itself.[1]
The Higman-Sims group can be constructed with the following two generators:[1]
and
Relationship to Conway groups
Conway (1968) identified the Higman–Sims group as a subgroup of the Conway group Co0. In Co0 HS arises as a pointwise stabilizer of a 2-3-3 triangle, one whose edges (differences of vertices) are type 2 and 3 vectors. HS thus is a subgroup of each of the Conway groups Co0, Co2 and Co3.
Wilson (2009) (p. 208) shows that the group HS is well-defined. In the Leech lattice, suppose a type 3 point v is fixed by an instance of Co3. Count the type 2 points w such that the inner product v·w = 2 (and thus v-w is type 3). He shows that their number is 11,178 = 2⋅35⋅23 and that this Co3 is transitive on these w.
|HS| = |Co3|/11,178 = 44,352,000.
In fact, |HS| = 100|M22| and there are instances of HS including a permutation matrix representation of the Mathieu group M22.
If an instance of HS in Co0 fixes a particular point of type 3, this point is found in 276 triangles of type 2-2-3 that this copy of HS permutes in orbits of 176 and 100. This fact leads to Graham Higman's construction as well as to the Higman–Sims graph. HS is doubly transitive on the 176 and rank 3 on the 100.
A 2-3-3 triangle defines a 2-dimensional subspace fixed pointwise by HS. The standard representation of HS can thus be reduced to a 22-dimensional one.
A Higman-Sims graph
Wilson (2009) (p. 210) gives an example of a Higman-Sims graph within the Leech lattice, permuted by the representation of M22 on the last 22 coordinates:
- 22 points of shape (1, 1, −3, 121)
- 77 points of shape (2, 2, 26, 016)
- A 100th point (4, 4, 022)
Differences of adjacent points are of type 3; those of non-adjacent ones are of type 2.
Here, HS fixes a 2-3-3 triangle with vertices x = (5, 123), y = (1, 5, 122), and z the origin. x and y are of type 3 while x-y = (4, −4, 022) is of type 2. Any vertex of the graph differs from x, y, and z by vectors of type 2.
Two classes of involutions
An involution in the subgroup M22 transposes 8 pairs of co-ordinates. As a permutation matrix in Co0 it has trace 8. It can shown that it moves 80 of the 100 vertices of the Higman-Sims graph. No transposed pair of vertices is an edge in the graph.
There is another class of involutions, of trace 0, that move all 100 vertices.[2] As permutations in the alternating group A100, being products of an odd number (25) of double transpositions, these involutions lift to elements of order 4 in the double cover 2.A100. HS thus has a double cover 2.HS.
Maximal subgroups
Magliveras (1971) found the 12 conjugacy classes of maximal subgroups of HS as follows:
Subgroup | Order | Index | Orbits on Higman-Sims graph | |
---|---|---|---|---|
M22 | 443520 | 100 | 1, 22, 77 | one-point stabilizer on Higman-Sims graph |
U3(5):2 | 252000 | 176 | imprimitive on pair of Hoffman-Singleton graphs of 50 vertices each | one-point stabilizer in doubly transitive representation of degree 176 |
U3(5):2 | 252000 | 176 | like type above | fused in HS:2 to class above |
PSL(3,4).2 | 40320 | 1100 | 2, 42, 56 | stabilizer of edge |
S8 | 40320 | 1100 | 30, 70 | |
24.S6 | 11520 | 3850 | 2, 6, 32, 60 | stabilizer of non-edge |
43:PSL(3,2) | 10752 | 4125 | 8, 28, 64 | |
M11 | 7920 | 5600 | 12, 22, 66 | classes fused in HS:2 |
M11 | 7920 | 5600 | 12, 22, 66 | |
4.24.S5 | 7680 | 5775 | 20, 80 | centralizer of involution class 2A moving 80 vertices of Higman–Sims graph |
2 × A6.22 | 2880 | 15400 | 40, 60 | centralizer of involution class 2B moving all 100 vertices |
5:4 × A5 | 1200 | 36960 | imprimitive on 5 blocks of 20 | normalizer of 5-subgroup generated by class 5B element |
Conjugacy classes
Traces of matrices in a standard 24-dimensional representation of HS are shown. [3] Listed are 2 permutation representations: on the 100 vertices of the Higman–Sims graph, and on the 176 points of Graham Higman's geometry.[4]
Class | Order of centralizer | No. elements | Trace | On 100 | On 176 | |
---|---|---|---|---|---|---|
1A | 44,352,000 | 1 = 1 | 24 | |||
2A | 7,680 | 5775 = 3 · 52 · 7 · 11 | 8 | 120,240 | 116,280 | |
2B | 2,880 | 15400 = 23 · 52 · 5 · 7 · 11 | 0 | 250 | 112, 282 | |
3A | 360 | 123200 = 26 · 52 · 7 · 11 | 6 | 110,330 | 15,357 | |
4A | 3,840 | 11550 = 2 · 3 · 52 · 7 · 11 | -4 | 210420 | 116,440 | |
4B | 256 | 173250 = 2 · 32 · 53 · 7 · 11 | 4 | 18,26,420 | 28,440 | |
4C | 64 | 693000 = 23 · 32 · 53 · 7 · 11 | 4 | 14,28,420 | 14,26,440 | |
5A | 500 | 88704 = 27 · 32 · 7 · 11 | -1 | 520 | 1,535 | |
5B | 300 | 147840 = 27 · 3 · 5 · 7 · 11 | 4 | 520 | 16,534 | |
5C | 25 | 1774080 = 29 · 32 · 5 · 7 | 4 | 15,519 | 1,535 | |
6A | 36 | 1232000 = 27 · 53 · 7 · 11 | 0 | 25,615 | 13,2,33,627 | |
6B | 24 | 1848000 = 26 · 3 · 53 · 7 · 11 | 2 | 12,24,36,612 | 1, 22,35,626 | |
7A | 7 | 6336000 = 29 · 32 · 53 · 11 | 3 | 12,714 | 1,725 | |
8A | 16 | 2772000 = 25 · 32 · 53 · 7 · 11 | 2 | 12,23,43,810 | 44, 820 | |
8B | 16 | 2772000 = 25 · 32 · 53 · 7 · 11 | 2 | 22,44,810 | 12,2,43,820 | |
8C | 16 | 2772000 = 25 · 32 · 53 · 7 · 11 | 2 | 22,44,810 | 12 2, 43, 820 | |
10A | 20 | 2217600 = 27 · 32 · 52 · 7 · 11 | 3 | 54,108 | 1,53,1016 | |
10B | 20 | 2217600 = 27 · 32 · 52 · 7 · 11 | 0 | 1010 | 12,22,52,1016 | |
11A | 11 | 4032000 = 29 · 32 · 53 · 7 | 2 | 11119 | 1116 | Power equivalent |
11B | 11 | 4032000 = 29 · 32 · 53 · 7 | 2 | 11119 | 1116 | |
12A | 12 | 3696000 = 27 · 3 · 53 · 7 · 11 | 2 | 21,42,63,126 | 1,35,4,1213 | |
15A | 15 | 2956800 = 29 · 3 · 52 · 7 · 11 | 1 | 52,156 | 32,5,1511 | |
20A | 20 | 2217600 = 27 · 32 · 52 · 7 · 11 | 1 | 102,204 | 1,53,208 | Power equivalent |
20B | 20 | 2217600 = 27 · 32 · 52 · 7 · 11 | 1 | 102,204 | 1,53,208 |
Generalized Monstrous Moonshine
Conway and Norton suggested in their 1979 paper that monstrous moonshine is not limited to the monster group, but that similar phenomena may be found for other groups. Larissa Queen and others subsequently found that one can construct the expansions of many Hauptmoduln from simple combinations of dimensions of sporadic groups. For HS, the McKay-Thompson series is where one can set a(0) = 4 (OEIS: A058097),
References
- https://www.gap-system.org/Doc/Examples/co3.html
- Wilson (2009), p. 213
- Conway et al. (1985)
- http://brauer.maths.qmul.ac.uk/Atlas/v3/spor/HS/#reps
- Conway, John Horton (1968), "A perfect group of order 8,315,553,613,086,720,000 and the sporadic simple groups", Proceedings of the National Academy of Sciences of the United States of America, 61 (2): 398–400, doi:10.1073/pnas.61.2.398, ISSN 0027-8424, MR 0237634, PMC 225171, PMID 16591697
- J. S. Frame (1972) 'Computations of Characters of the Higman-Sims Group and its Automorphism Group' Journal of Algebra, 20, 320-349
- Conway, John Horton; Parker, Richard A.; Norton, Simon P.; Curtis, R. T.; Wilson, Robert A. (1985), Atlas of finite groups, Oxford University Press, ISBN 978-0-19-853199-9, MR 0827219
- Dixon, John D.; Mortimer, Brian (1996), Permutation groups, Graduate Texts in Mathematics, 163, Berlin, New York: Springer-Verlag, doi:10.1007/978-1-4612-0731-3, ISBN 978-0-387-94599-6, MR 1409812
- Gallian, Joseph (1976), "The search for finite simple groups", Mathematics Magazine, 49 (4): 163–180, doi:10.2307/2690115, ISSN 0025-570X, JSTOR 2690115, MR 0414688
- Griess, Robert L. Jr. (1998), Twelve sporadic groups, Springer Monographs in Mathematics, Berlin, New York: Springer-Verlag, doi:10.1007/978-3-662-03516-0, ISBN 978-3-540-62778-4, MR 1707296
- Higman, Donald G.; Sims, Charles C. (1968), "A simple group of order 44,352,000" (PDF), Mathematische Zeitschrift, 105 (2): 110–113, doi:10.1007/BF01110435, ISSN 0025-5874, MR 0227269
- Higman, Graham (1969), "On the simple group of D. G. Higman and C. C. Sims", Illinois Journal of Mathematics, 13: 74–80, doi:10.1215/ijm/1256053736, ISSN 0019-2082, MR 0240193
- Magliveras, Spyros S. (1971), "The subgroup structure of the Higman–Sims simple group", Bulletin of the American Mathematical Society, 77 (4): 535–539, doi:10.1090/S0002-9904-1971-12743-X, ISSN 0002-9904, MR 0283077
- Wilson, Robert A. (2009), The finite simple groups., Graduate Texts in Mathematics 251, Berlin, New York: Springer-Verlag, doi:10.1007/978-1-84800-988-2, ISBN 978-1-84800-987-5, Zbl 1203.20012