List of small groups: Difference between revisions
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<th rowspan="9">16<ref>Wild, Marcel. "[http://math.sun.ac.za/~wild/Marcel%20Wild%20-%20Home%20Page_files/Groups16AMM.pdf The Groups of Order Sixteen Made Easy]", [[American Mathematical Monthly]], Jan 2005</ref></th> |
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<td>Dih<sub>8</sub></td> |
<td>Dih<sub>8</sub></td> |
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<td>Z<sub>8</sub>, Dih<sub>4</sub> (2), Z<sub>2</sub><sup>2</sup> (4), Z<sub>4</sub>, Z<sub>2</sub> (9)</td> |
<td>Z<sub>8</sub>, Dih<sub>4</sub> (2), Z<sub>2</sub><sup>2</sup> (4), Z<sub>4</sub>, Z<sub>2</sub> (9)</td> |
Revision as of 02:46, 15 May 2007
The following list in mathematics contains the finite groups of small order up to group isomorphism.
The list can be used to determine which known group a given finite group G is isomorphic to: first determine the order of G, then look up the candidates for that order in the list below. If you know whether G is abelian or not, some candidates can be eliminated right away. To distinguish between the remaining candidates, look at the orders of your group's elements, and match it with the orders of the candidate group's elements.
Glossary
- Zn: the cyclic group of order n (often the notation Cn is used, or Z / n Z).
- Dihn: the dihedral group of order 2n (often the notation Dn is used, and sometimes D2n )
- Sn: the symmetric group of degree n, containing the n! permutations of n elements.
- An: the alternating group of degree n, containing the n!/2 even permutations of n elements.
- Dicn: the dicyclic group of order 4n.
The notations Zn and Dihn have the advantage that point groups in three dimensions Cn and Dn do not have the same notation. There are more isometry groups than these two, of the same abstract group type.
The notation G × H stands for the direct product of the two groups; Gn denotes the direct product of a group with itself n times. Abelian and simple groups are noted. (For groups of order n < 60, the simple groups are precisely the cyclic groups Zn, where n is prime.) We use the equality sign ("=") to denote isomorphism.
The identity element in the cycle graphs is represented by the black circle. The lowest order for which the cycle graph does not uniquely represent a group is order 16.
In the lists of subgroups the trivial group and the group itself are not listed. Where there are multiple isomorphic subgroups, their number is indicated in parentheses.
List of small abelian groups
Order | Group | Subgroups | Properties | Cycle graph |
---|---|---|---|---|
1 | trivial group = Z1 = S1 = A2 | - | various properties hold trivially | |
2 | Z2 = S2 = Dih1 | - | simple, the smallest non-trivial group | |
3 | Z3 = A3 | - | simple | |
4 | Z4 | Z2 | ||
Klein four-group = Z2 2 = Dih2 | Z2 (3) | the smallest non-cyclic group | ||
5 | Z5 | - | simple | |
6 | Z6 = Z3 × Z2 | Z3 , Z2 | ||
7 | Z7 | - | simple | |
8 | Z8 | Z4 , Z2 | ||
Z4 ×Z2 | Z22, Z4 (2), Z2 (3) | |||
Z23 | Z22 (7) , Z2 (7) | the non-identity elements correspond to the points in the Fano plane, the Z2 × Z2 subgroups to the lines | ||
9 | Z9 | Z3 | ||
Z32 | Z3 (4) | |||
10 | Z10 = Z5 × Z2 | Z5 , Z2 | ||
11 | Z11 | - | simple | |
12 | Z12 = Z4 × Z3 | Z6 , Z4 , Z3 , Z2 | ||
Z6 × Z2 = Z3 × Z22 | Z6 (2), Z3, Z2 (3) | |||
13 | Z13 | - | simple | |
14 | Z14 = Z7 × Z2 | Z7 , Z2 | ||
15 | Z15 = Z5 × Z3 | Z5 , Z3 | ||
16 | Z16 | Z8 , Z4 , Z2 | ||
Z24 | Z2 (15) , Z22 (35) , Z23 (15) | |||
Z4 × Z22 | Z2 (7) , Z4 (4) , Z22 (7) , Z23, Z4 × Z2 (6) | |||
Z8 × Z2 | Z2 (3) , Z4 (2) , Z22, Z8 (2) , Z4 × Z2 | |||
Z42 | Z2 (3), Z4 (6) , Z22, Z4 × Z2 (3) |
List of small non-abelian groups
Order | Group | Subgroups | Properties | Cycle Graph |
---|---|---|---|---|
6 | S3 = Dih3 | Z3 , Z2 (3) | the smallest non-abelian group | |
8 | Dih4 | Z4, Z22 (3) , Z2 (5) | ||
Quaternion group, Q8 = Dic2 | Z4 (3), Z2 | the smallest Hamiltonian group | ||
10 | Dih5 | Z5 , Z2 (5) | ||
12 | Dih6 = Dih3 × Z2 | Z6 , Dih3 (2) , Z22 (3) , Z3 , Z2 (7) | ||
A4 | Z22 , Z3 (4) , Z2 (3) | smallest group demonstrating that the converse of Lagrange's theorem is not true: no subgroup of order 6 | ||
Dic3 = the semidirect product of Z3 and Z4, where Z4 acts on Z3 by inversion | Z2, Z3, Z4 (3), Z6 | |||
14 | Dih7 | Z7, Z2 (7) | ||
16[1] | Dih8 | Z8, Dih4 (2), Z22 (4), Z4, Z2 (9) | ||
Dih4 × Z2 | Dih4 (2), Z4 × Z2, Z23 (2), Z22 (7), Z4 (2), Z2 (11) | |||
Generalized quaternion group, Q16 = Dic4 | ||||
Q8 × Z2 | Hamiltonian | |||
The order 16 quasidihedral group | ||||
The order 16 modular group | ||||
The semidirect product of Z4 and Z4 where one factor acts on the other by inversion | ||||
The group generated by the Pauli matrices | ||||
G4,4 |
Small groups library
The group theoretical computer algebra system GAP contains the "Small Groups library" which provides access to descriptions of the groups of "small" order. The groups are listed up to isomorphism. At present, the library contains the following groups:
- those of order at most 2000 except for order 1024 (423 164 062 groups);
- those of order 55 and 74 (92 groups);
- those of order qn×p where qn divides 28, 36, 55 or 74 and p is an arbitrary prime which differs from q;
- those whose order factorises into at most 3 primes.
It contains explicit descriptions of the available groups in computer readable format.
The library has been constructed and prepared by Hans Ulrich Besche, Bettina Eick and Eamonn O'Brien; see http://www.tu-bs.de/~hubesche/small.html .
See also
External links
- ^ Wild, Marcel. "The Groups of Order Sixteen Made Easy", American Mathematical Monthly, Jan 2005