Isomorphisms of Groups

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Section Isomorphisms of Groups

Worksheet Part 1: Isomorphisms

The goal of these problems is to practice working with isomorphisms of groups.

1.

Let \(H\) be the subgroup of rotations in \(D_4\text{.}\) Show that \(H\cong \Z_4\text{.}\)

Solution.

We have \(H=\subgroup{r}\) so by Cyclic Groups are Isomorphic to \(\Z\) or \(\Z_n\) one isomorphism is \(r^k \mapsto k \pmod 4\text{.}\)

2.

Show that \(U(8)\) is not isomorphic to \(U(10)\text{.}\)

Solution.

As in \(U(10) \not\isom U(12)\) it is not possible for a map from \(U(10)\) to \(U(8)\) to be both operation preserving and bijective. Concretely, we must have

\begin{equation*} \phi(9)=\phi(3\cdot 3)=\phi(3)\cdot \phi(3)=(\phi(3))^2=1\text{,} \end{equation*}

since all elements of \(U(8)\) square to 1. But then \(\phi\) is not injective since \(\phi(1)=1\) as well.

Definition 57. Automorphism of a Group.

An automorphism of a group \(G\) is an isomorphism from \(G\) to itself. The set of all automorphisms of a group \(G\) forms a group under composition, called the automorphism group of \(G\text{,}\) denoted \(\Aut(G)\text{.}\)

3.

Let \(\R^+\) be the group of positive real numbers under multiplication. Show that the mapping \(\phi(x)=\sqrt{x}\) is an automorphism of \(\R^+\text{.}\)

Solution.

We have

\begin{equation*} \phi(xy)=\sqrt{xy}=\sqrt{x}\sqrt{y}=\phi(x)\phi(y) \end{equation*}

for any \(x,y\in \R^+\text{,}\) so \(\phi\) is operation preserving. Also, \(\phi\) is one-to-one since \(\phi(x)=\phi(y)\) implies \(\sqrt{x}=\sqrt{y}\) and hence \(x=y\text{.}\) Finally, \(\phi\) is onto since for any \(z\in \R^+\text{,}\) we have \(\phi(z^2)=z\text{.}\)

4. Conjugation is an Automorphism.

Let \(G\) be any group and \(a\in G\text{.}\) Show that the map \(\phi_a(g)=aga^{-1}\) is an automorphism of \(G\text{.}\)

Solution.

We have

\begin{equation*} \phi_a(gh)=a(gh)a^{-1}=(aga^{-1})(aha^{-1})=\phi_a(g)\phi_a(h) \end{equation*}

for any \(g,h\in G\text{,}\) so \(\phi_a\) is operation preserving. Also, \(\phi_{a^{-1}}\) is an inverse map for \(\phi_a\text{,}\) since

\begin{equation*} \phi_{a^{-1}} (\phi_a(g))=a^{-1}(aga^{-1})a=g=a(a^{-1}ga)a^{-1}=\phi_a(\phi_{a^{-1}}(g)) \end{equation*}

so \(\phi_a\) is bijective and hence an automorphism.