Dummit And Foote Solutions Chapter 4 Overleaf High Quality Guide

\subsection*Problem S4.1 \textitClassify all groups of order 8 up to isomorphism.

\subsection*Exercise 4.3.12 \textitProve that if $H$ is the unique subgroup of a finite group $G$ of order $n$, then $H$ is normal in $G$. Dummit And Foote Solutions Chapter 4 Overleaf High Quality

% Custom commands \newcommand\Z\mathbbZ \newcommand\Q\mathbbQ \newcommand\R\mathbbR \newcommand\C\mathbbC \newcommand\F\mathbbF \newcommand\Aut\operatornameAut \newcommand\Inn\operatornameInn \newcommand\sgn\operatornamesgn \newcommand\ord\operatornameord \newcommand\lcm\operatornamelcm \renewcommand\phi\varphi \subsection*Problem S4

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\subsection*Exercise 4.8.3 \textitShow that $\Inn(G) \cong G/Z(G)$. Dummit And Foote Solutions Chapter 4 Overleaf High Quality

\beginsolution Define $\phi: G \to \Aut(G)$ by $\phi(g) = \sigma_g$ where $\sigma_g(x) = gxg^-1$. The image is $\Inn(G)$. Kernel: $\phi(g) = \textid_G$ iff $gxg^-1=x$ for all $x\in G$ iff $g \in Z(G)$. By the first isomorphism theorem, \[ G / Z(G) \cong \Inn(G). \] \endsolution