Number of groups of given order: Difference between revisions

Revision as of 16:16, 17 April 2010

Definition

Let $n$ be a natural number. The number of groups of order $n$ is defined as the number of isomorphism classes of groups whose order is $n$ .

This is a finite number and is bounded by $n^{2n}$ for obvious reasons. The function is not strictly increasing in $n$ and depends heavily on the nature of the prime factorization of $n$ .

Initial values

The ID of the sequence of these numbers in the Online Encyclopedia of Integer Sequences is A000001

$n$	Number of groups of order $n$	Reason/explanation
1	1
2	1	prime number
3	1	prime number
4	2	square of a prime; see classification of groups of prime-square order
5	1	prime number
6	2	form $pq$ where $p,q$ primes, $q\mid p-1$
7	1	prime number
8	5	prime cube: classification of groups of prime-cube order, also see groups of order 8
9	2	prime square; see [[classification of groups of prime-square order

<toggledisplay>We omit the prime numbers since there is only one group of each such order.

$n$	Number of groups of order $n$	Reason/explanation
10	2	form $pq$ where $p,q$ primes, $q\mid p-1$
12	5	see groups of order 12
14	2	form $pq$ where $p,q$ primes, $q\mid p-1$
15	1	form $pq$ ( $p,q$ primes) where $p$ doesn't divide $q-1$ , $q$ doesn't divide $p-1$
16	14	see groups of order 16
18	5	see groups of order 18
20	5	see groups of order 20
21	2	form $pq$ where $p,q$ primes, $q\mid p-1$
22	2	form $pq$ where $p,q$ primes, $q\mid p-1$
24	15	see groups of order 24
25	2	prime square; see classification of groups of prime-square order
26	2	form $pq$ where $p,q$ primes, $q\mid p-1$
27	5	see classification of groups of prime-cube order
28	4
30	4
32	51
33	1	form $pq$ ( $p,q$ primes) where $p$ doesn't divide $q-1$ , $q$ doesn't divide $p-1$
34	2	form $pq$ where $p,q$ primes, $q\mid p-1$
35	1	form $pq$ ( $p,q$ primes) where $p$ doesn't divide $q-1$ , $q$ doesn't divide $p-1$
36	14	see groups of order 36

Facts

Basic facts

Value of $n$	What we can say about the number of groups of order $n$	Explanation
1	1	only the trivial group
$p$ a prime number	1	only the group of prime order. See equivalence of definitions of group of prime order
$p^{2}$ , $p$ prime	2	only the cyclic group of prime-square order and the elementary abelian group of prime-square order
$p^{3}$ , $p$ prime	5	see classification of groups of prime-cube order
$2^{4}=16$	14	see classification of groups of order 16, also groups of order 16 for summary information.
$p^{4}$ , $p$ odd prime	15	see classification of groups of prime-fourth order for odd prime
product $p_{1}p_{2}\dots p_{n}$ , $p_{i}$ distinct primes with no $p_{i}$ dividing $p_{j}-1$	1	the cyclic group of that order. See classification of cyclicity-forcing numbers

Asymptotic fact

Properties

Supermultiplicativity

If $n=ab$ with $a$ and $b$ relatively prime, the number of groups of order $n$ is bounded from below by the product of the number of groups of orders $a$ and $b$ respectively. This is because we can take direct products for every pair of a group of order $a$ and a group of order $b$ .

@@ Line 5: / Line 5: @@
 This is a finite number and is bounded by <math>n^{2n}</math> for obvious reasons. The function is ''not'' strictly increasing in <math>n</math> and depends heavily on the nature of the prime factorization of <math>n</math>.
+==Initial values==
+{{oeis|A000001}}
+{| class="wikitable" border="1"
+! <math>n</math> !! Number of groups of order <math>n</math> !! Reason/explanation
+|-
+| 1 || 1 ||
+|-
+| 2 || 1 || [[prime number]]
+|-
+| 3 || 1 || [[prime number]]
+|-
+| 4 || 2 || square of a prime; see [[classification of groups of prime-square order]]
+|-
+| 5 || 1 || [[prime number]]
+|-
+| 6 || 2 || form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 7 || 1 || [[prime number]]
+|-
+| 8 || 5 || prime cube: [[classification of groups of prime-cube order]], also see [[groups of order 8]]
+|-
+| 9 || 2 || prime square; see [[classification of groups of prime-square order
+|}
+<toggledisplay>We omit the prime numbers since there is only one group of each such order.
+{| class="wikitable" border="1"
+! <math>n</math> !! Number of groups of order <math>n</math> !! Reason/explanation
+|-
+| 10 || 2 || form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 12 || 5 || see [[groups of order 12]]
+|-
+| 14 || 2 || form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 15 || 1 || form <math>pq</math> (<math>p,q</math> primes) where <math>p</math> doesn't divide <math>q - 1</math>, <math>q</math> doesn't divide <math>p - 1</math>
+|-
+| 16 || 14 || see [[groups of order 16]]
+|-
+| 18 || 5 || see [[groups of order 18]]
+|-
+| 20 || 5 || see [[groups of order 20]]
+|-
+| 21 || 2 || form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 22 || 2 || form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 24 || 15 || see [[groups of order 24]]
+|-
+| 25 || 2 || prime square; see [[classification of groups of prime-square order]]
+|-
+| 26 || 2 || form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 27 || 5 || see [[classification of groups of prime-cube order]]
+|-
+| 28 || 4 ||
+|-
+| 30 || 4 ||
+|-
+| 32 || 51 ||
+|-
+| 33 || 1 || form <math>pq</math> (<math>p,q</math> primes) where <math>p</math> doesn't divide <math>q - 1</math>, <math>q</math> doesn't divide <math>p - 1</math>
+|-
+| 34 || 2 ||form <math>pq</math> where <math>p,q</math> primes, <math>q \mid p - 1</math>
+|-
+| 35 || 1 || form <math>pq</math> (<math>p,q</math> primes) where <math>p</math> doesn't divide <math>q - 1</math>, <math>q</math> doesn't divide <math>p - 1</math>
+|-
+| 36 || 14 || see [[groups of order 36]]
+|}
 ==Facts==
 ===Basic facts===