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Harada–Norton group

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Algebraic groups

In the area of modern algebra known as group theory, the Harada–Norton group HN is a sporadic simple group of order

   273,030,912,000,000
= 2 ···· 11 · 19
≈ 3×10.

History and properties

HN is one of the 26 sporadic groups and was found by Harada (1976) and Norton (1975)).

Its Schur multiplier is trivial and its outer automorphism group has order 2.

HN has an involution whose centralizer is of the form 2.HS.2, where HS is the Higman-Sims group (which is how Harada found it).

The prime 5 plays a special role in the group. For example, it centralizes an element of order 5 in the Monster group (which is how Norton found it), and as a result acts naturally on a vertex operator algebra over the field with 5 elements (Lux, Noeske & Ryba 2008). This implies that it acts on a 133 dimensional algebra over F5 with a commutative but nonassociative product, analogous to the Griess algebra (Ryba 1996).

The full nomralizer of a 5A element in the Monster group is (D10 × HN).2, so HN centralizes 5 involutions alongside the 5-cycle. These involutions are centralized by the Baby monster group, which therefore contains HN as a subgroup.

Generalized monstrous moonshine

Conway and Norton suggested in their 1979 paper that monstrous moonshine is not limited to the monster, 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. To recall, the prime number 5 plays a special role in the group and for HN, the relevant McKay-Thompson series is T 5 A ( τ ) {\displaystyle T_{5A}(\tau )} where one can set the constant term a(0) = −6 (OEISA007251),

j 5 A ( τ ) = T 5 A ( τ ) 6 = ( η ( τ ) η ( 5 τ ) ) 6 + 5 3 ( η ( 5 τ ) η ( τ ) ) 6 = 1 q 6 + 134 q + 760 q 2 + 3345 q 3 + 12256 q 4 + 39350 q 5 + {\displaystyle {\begin{aligned}j_{5A}(\tau )&=T_{5A}(\tau )-6\\&=\left({\frac {\eta (\tau )}{\eta (5\tau )}}\right)^{6}+5^{3}\left({\frac {\eta (5\tau )}{\eta (\tau )}}\right)^{6}\\&={\frac {1}{q}}-6+134q+760q^{2}+3345q^{3}+12256q^{4}+39350q^{5}+\dots \end{aligned}}}

and η(τ) is the Dedekind eta function.

Maximal subgroups

Norton & Wilson (1986) found the 14 conjugacy classes of maximal subgroups of HN as follows:

Maximal subgroups of HN
No. Structure Order Index Comments
1 A12 239,500,800
= 2·3·5·7·11
1,140,000
= 2·3·5·19
2 2HS.2 177,408,000
= 2·3·5·7·11
1,539,000
= 2·3·5·19
centralizer of an involution of class 2A
3 U3(8):3 16,547,328
= 2·3·7·19
16,500,000
= 2·3·5·11
4 2.(A5 × A5).2 3,686,400
= 2·3·5
74,064,375
= 3·5·7·11·19
centralizer of an involution of class 2B
5 (D10 × U3(5)).2 2,520,000
= 2·3·5·7
108,345,600
= 2·3·5·11·19
normalizer of a subgroup of order 5 (class 5A)
6 5.2.5.4 2,000,000
= 2·5
136,515,456
= 2·3·7·11·19
normalizer of a subgroup of order 5 (class 5B)
7 2.U4(2) 1,658,880
= 2·3·5
164,587,500
= 2·3·5·7·11·19
8 (A6 × A6).D8 1,036,800
= 2·3·5
263,340,000
= 2·3·5·7·11·19
9 2.(3 × L3(2)) 1,032,192
= 2·3·7
264,515,625
= 3·5·11·19
10 5.4.A5 750,000
= 2·3·5
364,041,216
= 2·3·7·11·19
11,12 M12:2 190,080
= 2·3·5·11
1,436,400,000
= 2·3·5·7·19
two classes, fused by an outer automorphism
13 3:2.(A4 × A4).4 93,312
= 2·3
2,926,000,000
= 2·5·7·11·19
14 3:4.A5 58,320
= 2·3·5
4,681,600,000
= 2·5·7·11·19
normalizer of a subgroup of order 3 (class 3B)

References

External links

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