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It's often said that there are only two nonabelian groups of order 8 up to isomorphism, one is the quaternion group, the other given by the relations $a^4=1$, $b^2=1$ and $bab^{-1}=a^3$.

I've never understood why these are the only two. Is there a reference or proof walkthrough on how to show any nonabelian group of order 8 is isomorphic to one of these?

  • 8
    Since $G$ is a $p$-group, then $Z(G)$ must be nontrivial, and $G/Z(G)$ cannot be cyclic since $G$ is nonabelian. This should get you started.2011-09-14

5 Answers 5

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A very down-to-Earth approach might be:

Let $G$ be a group of order 8.

Exercise 1: Show that the maximal order $m$ of an element $x$ of $G$ is either 2, 4, or 8.

Exercise 2: Show that if $m=2$, then the group $G$ is abelian.

Exercise 3: Show that if $m=8$, then the group $G$ is abelian.

Ok, so that leaves us with the case $m=4$. Let $x$ be an element of order 4. Let $H\simeq C_4$ be the subgroup generated by $x$.

Exercise 4: Show that $H$ is a normal subgroup of $G$.

Let $y\in G, y\notin H$ be a fixed element.

Exercise 5: Show that $y^2\in H$.

Exercise 6: Show that $yxy^{-1}$ is an element of order 4 in $H$.

Exercise 7: Show that either $yxy^{-1}=x$ or $yxy^{-1}=x^3$.

Exercise 8: Show that if $yxy^{-1}=x$, then $G$ is abelian.

Ok, so we must have $yxy^{-1}=x^3.$ Assume that this is the case in what follows.

Exercise 9: Show that if $y$ is of order 2, then $G$ is isomorphic to a dihedral group.

Exercise 10: Show that if $y$ is of order 4, then $y^2=x^2$.

Exercise 11: Show that if $y$ is of order 4, then $G$ is isomorphic to the quaternion group (or more precisely: the group of units of the Lipschitz' order)

Rejoice!

Remark: You won't need the result of Exercise 5 until the two last ones. I just added it there, because the element $y$ was introduced at that point.

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See www.math.uconn.edu/~kconrad/blurbs/grouptheory/groupsp3.pdf, which discusses groups of order p^3 for any prime p and treats the case p = 2 first.

  • 1
    Please see http://meta.math.stackexchange.com/questions/415/homework-questions-avoiding-giving-a-complete-solution. I feel that although this is not a homework question there is no reason that it should not be treated as one. Indeed, I believe I was asked it as a homework question during my undergrad.2011-09-15
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Here's the proof that there are exactly five nonisomorphic groups of order $p^3$ for every prime $p$, as it appears in Marshall Hall's Theory of Groups.

  1. The abelian case is easy: you have $C_{p^3}$, $C_{p^2}\times C_p$, and $C_{p}\times C_p\times C_p$.

  2. The nonabelian case. There can be no element of order $p^3$, because then the group is cyclic.

    • If all elements are of order $p$, then $p$ must be odd (otherwise the group is abelian). The center of $G$ is of order $p$ (since the quotient must be of order $p^2$ and isomorphic to $C_p\times C_p$); let $x$ and $y$ be elements of $G$ whose images generate the two cyclic factors of $G/Z(G)$. Then $x^p = y^p = 1$, and $x^{-1}y^{-1}xy\neq 1$ (otherwise, $G$ would be abelian), but must be central; so $z=x^{-1}y^{-1}xy$ generates $Z(G)$. So $G$ is given by $G = \langle x,y,z\mid x^p=y^p=z^p=1, xy=yxz,\ xz=zx,\ yz=zy\rangle.$

    • If there is an element $x$ of order $p^2$, then $\langle x\rangle$ is a maximal abelian subgroup of $G$, and normal (since its index is the smallest prime that divides $|G|$. Let $b\notin A$. Then $b^p\in A$, and $b^{-1}ab=a^r$ for some $r$; since $G$ is nonabelian, $r\neq 1$. Since $b^p$ commutes with $a$, $a^{r^p}=a$, so $r^p\equiv 1\pmod{p^2}$. From Fermat's Little Theorem, $r^p\equiv r\pmod{p}$, so $r\equiv 1\pmod{p}$.

      Write $r=1+sp$, and let $j$ such that $js\equiv 1\pmod{p}$. Then $b^{-j}ab^j = a^{r^j} = a^{(1+sp)^j} = a^{1+spj} =a^{1+p}.$ Since $(j,p)=1$, $b^j\notin A$, so replacing $b$ with $b^j$, we may assume that $b^{-1}ab=a^{1+p}$.

      Now, $b^p = a^t$, and $t$ must be a multiple of $t$, because $b$ is not of order $p^3$. Write $t=up$, so $b^p=a^{up}$. Then we have: $\begin{align*} (ba^{-u})^p &= b^pa^{-u(1+(1+p)+(1+p)^2 + \cdots + (1+p)^{p-1})}\\ &= b^p a^{-up-up(1+2+\cdots + p-1)}\\ &= b^p a^{-up-up\binom{p}{2}}. \end{align*}$

      • If $p$ is odd, then $up\binom{p}{2}$ is a multiple of $p^2$, so we get $(ba^{-u})^p = b^pa^{-up} = b^pb^{-p} = 1$. Setting $c=ba^{-u}$ we get $c^{-1}ac = b^{-1}ab$, so the group is presented by $\langle a,c\mid a^{p^2} = c^p = 1,\ ac = ca^{1+p}.\rangle$

      • If $p$ is $2$, however, we get $(ba^{-u})^2 = b^2a^{-up-up} = b^2$. We have two possibilities: it could be that $b^2=1$, in which case we get the same presentation as above: $\langle a,b\mid a^{4} = b^2 = 1,\ ab=ba^3\rangle.$ Or it could be that $b^2=a^2$; we must have $b^{-1}ab=a^3$ (it cannot equal $a$, because then $a$ and $b$ commute and $G$ is abelian), so the group is given by $\langle a,b\mid a^4=1,\ a^2=b^2,\ ab=ba^3.$

Burnside uses essentially the same approach, though he only deals explicitly with odd $p$; the classification for groups of order $p^3$ takes up about two pages (one paragraph, but he invokes results covering two previous pages). He then proceeds to those of order $p^4$; that takes four and a half pages (plus invoking stuff that covers at least one previous page). He only lists those of order $2^3$ and $2^4$.

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Let $G$ be non-abelian group of order 8.

By Sylow theorem, $G$ will have subgroups of order 2.

  • If $G$ has unique subgroup of order 2, then $G$ is quaternion (Ref. Theorem 12.5.2, Theory of groups- Marshall Hall). ($G$ can be cyclic also, but we have assumed it is non-abelian.)

  • If $G$ has more than one subgroups of order 2, then they will be $1+2k$ in number for some $k\geq 1$; so it is atleast $3$; let $H_1, H_2, H_3$ be three distinct subgroups of order $2$.

If $H_1\triangleleft G$, then $G/H_1$ is abelian (since its order is 4), we conclude that $[G,G]\leq H_1$, hence $H_1=[G,G]$ since $G$ is non-abelian.

Then observe that $H_2$ can-not be normal in $G$, otherwise $H_2=[G,G]=H_1$, contradiction.

(So we have found a subgroup of order $2$ which is not normal in $G$.)

$H_2$ is a subgroup of $G$ index 4, there is a homomorphism $\phi \colon G\rightarrow S_4$, with $ker(\phi)\subseteq H_2$ (See "Generalised Cayley's theorem" - Introduction to Theory of Groups, Rotman).

But $ker(\phi)\neq H_2$ since $H_2$ is not normal, so $ker(\phi)=\{1\}$; so $G$ is isomorphic to a subgroup of $S_4$ of order $8$; it is a Sylow-2 subgroup of $S_4$; and it is $D_8$ since when considering a square with vertices labelled "1,2,3,4", its symmetries in terms of permutations give $D_8\leq S_4$.

Conclusion:

$G$ is either quaternion or isomorphic to Sylow-2 subgroup of $S_4$ which is dihedral group of order 8.

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You probably meant $bab = a^3$ in the above.

The following steps should also work. In order not to spoil the fun for you, I omit all the details.

Let $G$ be a nonabelian group of order $8$ and let $Z$ be its centre.

(1) From the class equation we know that $|Z|$ is divisible by $2$, and hence $|Z|\gt1$

(2) If $G/Z$ were cyclic then $G$ would be abelian. Therefore only the case $|Z|=2$ is possible and we know that $G/Z$ must be isomorphic to the Klein group.

Now let $Z=\{1,z\}$ and take $a,b,c\in G$ with $G/Z = \{Z, aZ, bZ, cZ\}$. All squares a^2, b^2, c^2 lie in $Z$ and we may take $c=ab$. Now the rest is a case by case analysis

(3) We cannot have $a^2 = b^2 = (ab)^2 = 1$, because then every element of $G$ would have order $2$, forcing $G$ to be abelian. So at least one of those squares must equal $z$. In particular $G$ has an element of order $4$.

(4) If two of the above squares equal $z$, then so does the third. For instance, suppose $a^2 = z = b^2$. Then $(ab)^2 = 1$ would give $ab=zbaz=ba$ and $G$ would be abelian.

So now we arrived at two possibilities (up to permutation of $a$, $b$ and $c$):

case (i): $a^2 = b^2 = c^2 = z$. Then $G$ is the quaternion group.

case (ii) $a^2 = z$, $b^2 = 1$. Then $bab$ lies in $aZ$. Because of (4), $bab=a$ is impossible and therefore $bab = az = a^3$.