Janko group J1
In the area of modern algebra known as group theory, the Janko group J1 is a sporadic simple group of order
History
is one of the 26 sporadic groups and was originally described by Zvonimir Janko in 1965. It is the only Janko group whose existence was proved by Janko himself and was the first sporadic group to be found since the discovery of the Mathieu groups in the 19th century. Its discovery launched the modern theory of sporadic groups.In 1986 Robert A. Wilson showed that cannot be a subgroup of the monster group. Thus it is one of the 6 sporadic groups called the pariahs.
Properties
The smallest faithful complex representation of has dimension 56. can be characterized abstractly as the unique simple group with abelian 2-Sylow subgroups and with an involution whose centralizer is isomorphic to the direct product of the group of order two and the alternating group of order 60, which is to say, the rotational icosahedral group. That was Janko's original conception of the group.In fact, Janko and Thompson were investigating groups similar to the Ree groups, and showed that if a simple group has abelian Sylow 2-subgroups and a centralizer of an involution of the form for a prime power at least 3, then either is a power of 3 and has the same order as a Ree group or is 4 or 5. Note that. This last exceptional case led to the Janko group.
has no outer automorphisms and its Schur multiplier is trivial.
is contained in the O'Nan group as the subgroup of elements fixed by an outer automorphism of order 2.
is the unique finite group with the property that for any nontrivial conjugacy class, every element of is equal to for some in.
Constructions
Modulo 11 representation
Janko found a modular representation in terms of orthogonal matrices in the field of eleven elements, with generators given byand
has order 7 and has order 5. Janko credited W. A. Coppel for recognizing this representation as an embedding into Dickson's simple group G2(11).
Permutation representation
is the automorphism group of the Livingstone graph, a distance-transitive graph with 266 vertices and 1463 edges. The stabilizer of a vertex is, and the stabilizer of an edge is.This permutation representation can be constructed implicitly by starting with the subgroup and adjoining 11 involutions. permutes these involutions under the exceptional 11-point representation, so they may be identified with points in the Payley biplane. The following relations are sufficient to define :
- Given points and, there are 2 lines containing both and, and 3 points lie on neither of these lines: the product is the unique involution in that fixes those 3 points.
- Given points,, and that do not lie in a common line, the product is the unique element of order 6 in that sends to, to, back to, so is the unique involution that fixes these 3 points.
Presentation
There is also a pair of generators, such thatis thus a Hurwitz group, a finite homomorphic image of the (2,3,7) triangle group.
Maximal subgroups
Janko found the 7 conjugacy classes of maximal subgroups of shown in the table. Maximal simple subgroups of order 660 afford a permutation representation of degree 266. He found that there are 2 conjugacy classes of subgroups isomorphic to the alternating group, both found in the simple subgroups of order 660. has non-abelian simple proper subgroups of only 2 isomorphism types.| No. | Structure | Order | Index | Description |
| 1 | L2 | 660 = 22·3·5·11 | 266 = 2·7·19 | fixes point in smallest permutation representation |
| 2 | 23:7:3 | 168 = 23·3·7 | 1,045 = 5·11·19 | normalizer of Sylow 2-subgroup |
| 3 | 2×A5 | 120 = 23·3·5 | 1,463 = 7·11·19 | centralizer of involution |
| 4 | 19:6 | 114 = 2·3·19 | 1,540 = 22·5·7·11 | normalizer of Sylow 19-subgroup |
| 5 | 11:10 | 110 = 2·5·11 | 1,596 = 22·3·7·19 | normalizer of Sylow 11-subgroup |
| 6 | D6×D10 | 60 = 22·3·5 | 2,926 = 2·7·11·19 | normalizer of Sylow 3-subgroup and Sylow 5-subgroup |
| 7 | 7:6 | 42 = 2·3·7 | 4,180 = 22·5·11·19 | normalizer of Sylow 7-subgroup |
In this table, is the dihedral group of order.
Number of elements of each order
The greatest order of any element of the group is 19. The conjugacy class orders and sizes are found in the ATLAS.| Order | No. elements | Conjugacy |
| 1 = 1 | 1 = 1 | 1 class |
| 2 = 2 | 1463 = 7 · 11 · 19 | 1 class |
| 3 = 3 | 5852 = 22 · 7 · 11 · 19 | 1 class |
| 5 = 5 | 11704 = 23 · 7 · 11 · 19 | 2 classes, power equivalent |
| 6 = 2 · 3 | 29260 = 22 · 5 · 7 · 11 · 19 | 1 class |
| 7 = 7 | 25080 = 23 · 3 · 5 · 11 · 19 | 1 class |
| 10 = 2 · 5 | 35112 = 23 · 3 · 7 · 11 · 19 | 2 classes, power equivalent |
| 11 = 11 | 15960 = 23 · 3 · 5 · 7 · 19 | 1 class |
| 15 = 3 · 5 | 23408 = 24 · 7 · 11 · 19 | 2 classes, power equivalent |
| 19 = 19 | 27720 = 23 · 32 · 5 · 7 · 11 | 3 classes, power equivalent |