Is there any theorem that states the all the finite groups of order n are the same? or some sort of theorem that refers to the order of two finite groups? If anyone can post a reference to this topic will be great... 10x in advance
About the Order of Groups
-
0@Gerenuk: your comment about finite fields is correct. However, there are very few finite fields: there is a field of order $n$ if and only if $n=p^m$ for some prime $p$, $m\in\mathbb{N}$. – 2012-05-07
4 Answers
No, this is unimaginably not true. In fact, there is a theorem which says that almost the opposite of what you have just said:
Theorem: Let $n\in\mathbb{N}$. Then, there exists only one group (up to isomorphism) of order $n$ if and only if $n=p_1\cdots p_m$ for distinct primes $p_i$, such that $p_i\not\equiv 1\text{ mod }p_j$ for any $i,j$.
This is a standard set of exercises in most algebra textbooks--ask if you'd like an explicit reference.
(I prove this on my blog, here)
-
0See also http://math.stackexchange.com/questions/106085/order-of-cyclic-groups-and-the-euler-phi-function and http://math.stackexchange.com/questions/67407/group-of-order-15-is-abelian/67469#67469. – 2012-05-07
Not all groups of order n are the same.
$\mathbb{Z}_6$ and $S_3$ are both of order 6. However $S_3$ has 3 subgroups of order 2, where $\mathbb{Z}_6$ has only one subgroup of order 2.
Therefore they cannot be isomorphic.
Consider the group $C_2\times C_2$ and $C_4$. Both of order $4$ but the latter has an element of order $4$ while the former does not
-
1I use $C_n$ to denote the cyclic group of $n$ elements. – 2012-05-07
You might want to read the paper of Besche, Eick and O'Brien http://www.math.auckland.ac.nz/~obrien/research/2000.pdf which contains a table of the number of groups of order $n<2001$.