Group Theory and Linear Algebra

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updated: 24 September 2014

Lecture 23: Quotient groups

Let $G$ be a group and let $H$ be a subgroup of $G\text{.}$ The set of cosets of $H$ in $G$ is $$\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.=\left\{gH\hspace{0.17em}\right|\hspace{0.17em}g\in G\},$$ where $gH=\left\{gh\hspace{0.17em}\right|\hspace{0.17em}h\in H\}$ for $g\in G\text{.}$

A normal subgroup of $G$ is a subgroup $K$ of $G$ such that if $g\in G$ and $k\in K$ then $gk{g}^{-1}\in K\text{.}$

Let $G$ be a group and let $H$ be a subgroup of $G\text{.}$ Then $\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ with $$\begin{array}{ccc}\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\times \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.& ⟶& \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\\ (g_{1}H,g_{2}H)& ⟼& g_1{g}_{2}H\end{array}$$ is a well defined group if and only if $H$ is a normal subgroup of $G\text{.}$

If $$\begin{array}{ccc}{\displaystyle G}& =& {\displaystyle \{\begin{array}{c}\end{array},\begin{array}{c}\end{array},\begin{array}{c}\end{array},\begin{array}{c}\end{array},\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}=S_3\text{and}}\\ {\displaystyle H}& =& {\displaystyle \{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}}\end{array}$$ the cosets in $\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ are $$\begin{array}{c}\begin{array}{c}\end{array}·H=\begin{array}{c}\end{array}·H=\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\},\\ \begin{array}{c}\end{array}·H=\begin{array}{c}\end{array}·H=\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\},\\ \begin{array}{c}\end{array}·H=\begin{array}{c}\end{array}·H=\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}\end{array}$$

If we try to define $$\begin{array}{cc}\begin{array}{ccc}\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\times \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.& ⟶& \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\\ (g_{1}H,g_{2}H)& ⟼& g_1{g}_{2}H\end{array}& (*)\end{array}$$ then (·H) (·H)= ·H= { , } = (·H) (·H)= ·H= { , } gives $${\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}}^2=\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}\text{and}{\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}}^2=\{\begin{array}{c}\end{array},\begin{array}{c}\end{array}\}\text{.}$$ In other words, for this $H,$ $(*)$ is not a function! The theorem tells us that this is "because" $H$ is not normal: $\begin{array}{c}\end{array}\in H,$ but $$\begin{array}{c}\end{array}·\begin{array}{c}\end{array}·{\left(\begin{array}{c}\end{array}\right)}^{-1}=\begin{array}{c}\end{array}·\begin{array}{c}\end{array}·\begin{array}{c}\end{array}=\underset{{\displaystyle \begin{array}{c}\end{array}}}{\overset{{\displaystyle \begin{array}{c}\end{array}}}{\begin{array}{c}\end{array}}}=\begin{array}{c}\end{array}$$ is not in $H\text{.}$

		Proof of the theorem.
	$\Leftarrow \text{:}$ Assume $H$ is a normal subgroup. To show: (a) $$\begin{array}{ccc}\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\times \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.& ⟶& \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\\ (g_{1}H,g_{2}H)& ⟼& g_1{g}_{2}H\end{array}$$ is a function. (b) Using $\left(g_{1}H\right)\left(g_{2}H\right)=g_1{g}_{2}H$ as product: (ba) If $g_{1}H,g_{2}H,g_{3}H\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then $$\left(g_{1}H{g}_{2}H\right)g_{3}H=g_{1}H\left(g_{2}H{g}_{3}H\right)\text{.}$$ (bb) There exists $eH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ such that if $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then $\left(eH\right)\left(gH\right)=gH$ and $\left(gH\right)\left(eH\right)=gH\text{.}$ (bc) If $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then there exists $xH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ such that $\left(xH\right)\left(gH\right)=eH$ and $\left(gH\right)\left(xH\right)=eH\text{.}$ (a) To show: If $(g_{1}H,g_{2}H)=(g_1^{\prime }H,g_2^{\prime }H)$ then $g_1{g}_{2}H=g_1^{\prime }{g}_2^{\prime }H\text{.}$ Assume $(g_{1}H,g_{2}H)=(g_1^{\prime },g_2^{\prime }H)\text{.}$ Then $g_{1}H=g_1^{\prime }H$ and $g_{2}H=g_2^{\prime }\text{.}$ To show: $g_1{g}_{2}H=g_1^{\prime }{g}_2^{\prime }H\text{.}$ To show: $g_1{g}_2\in g_1^{\prime }{g}_2^{\prime }H,$ since the cosets partition $G\text{.}$ We know $g_1\in g_1^{\prime }H$ and $g_2\in g_2^{\prime }H\text{.}$ So there exist $h_1,h_2\in H$ such that $g_1=g_1^{\prime }{h}_1$ and $g_2=g_2^{\prime }{h}_2\text{.}$ To show: $g_1{g}_2\in g_1^{\prime }{g}_2^{\prime }H\text{.}$ $$\begin{array}{ccc}{\displaystyle g_1{g}_2}& =& {\displaystyle g_1^{\prime }{h}_1{g}_2^{\prime }{h}_2}\\ & =& {\displaystyle g_1^{\prime }{g}_2^{\prime }{\left(g_2^{\prime }\right)}^{-1}{h}_1{g}_2^{\prime }{h}_2}\\ & =& {\displaystyle g_1^{\prime }{g}_2^{\prime }\left({\left(g_2^{\prime }\right)}^{-1}{h}_1{g}_2^{\prime }\right)h_2\in g_1^{\prime }{g}_2^{\prime }H}\end{array}$$ since $H$ is a normal subgroup of $G\text{.}$ (b) Use $\left(g_{1}H\right)\left(g_{2}H\right)=g_1{g}_{2}H$ as product in $\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\text{.}$ (ba) To show: If $g_{1}H,g_{2}H,g_{3}H\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then $\left(g_{1}H{g}_{2}H\right)g_{3}H=g_{1}H\left(g_{2}H{g}_{3}H\right)\text{.}$ Assume $g_{1}H,g_{2}H,g_{3}H\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\text{.}$ To show: $\left(g_{1}H{g}_{2}H\right)g_{3}H=g_{1}H\left(g_{2}H{g}_{3}H\right)\text{.}$ Then $$\left(g_{1}H{g}_{2}H\right)g_{3}H=g_1{g}_{2}H·g_{3}H=\left(g_1{g}_2\right)g_{3}H$$ and $$g_{1}H\left(g_{2}H{g}_{3}H\right)=g_{1}H·g_2{g}_{3}H=g_1\left(g_2{g}_3\right)H$$ and $\left(g_1{g}_2\right)g_3=g_1\left(g_2{g}_3\right)$ since $G$ is associative. So $\left(g_{1}H{g}_{2}H\right)g_{3}H=g_{1}H\left(g_{2}H{g}_{3}H\right)\text{.}$ (bb) To show: There exist $eH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ such that if $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then $\left(eH\right)\left(gH\right)=gH$ and $\left(gH\right)\left(eH\right)=gH\text{.}$ Let $eH=H\text{.}$ To show: if $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then $\left(eH\right)\left(gH\right)=gH$ and $\left(gH\right)\left(eH\right)=gH\text{.}$ Assume $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\text{.}$ To show: (bba) $eH·gH=gH\text{.}$ (bbb) $gH·eH=gH\text{.}$ (bba) $$eH·gH=1·H·g·H=1\left(g\right)H=gH,$$ since $1$ is an identity for $G\text{.}$ (bbb) $$gHeH=gH1·H=\left(g1\right)·H=gH\text{.}$$ (bc) To show: If $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ then there exists $xH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ such that $\left(gH\right)\left(xH\right)=eH$ and $xHgH=H\text{.}$ Assume $gH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.\text{.}$ To show: There exists $xH\in \raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ such that $$gHxH=H\text{and}xHgH=H\text{.}$$ Let $xH=g^{-1}H\text{.}$ To show: (bca) $gHxH=H\text{.}$ (bcb) $xHgH=H\text{.}$ (bca) $$gHxH=gH{g}^{-1}H=g{g}^{-1}H=1·H=H\text{.}$$ (bcb) $$xHgH=g^{-1}HgH=\left(g{g}^{-1}\right)H=1·H=H\text{.}$$ This completed the proof that if $H$ is a normal subgroup of $G$ then $\raisebox{1ex}{$G$}\!\left/ \!\raisebox{-1ex}{$H$}\right.$ with $\left(g_{1}H\right)\left(g_{2}H\right)=g_1{g}_{2}H$ is a group. $\square$

Notes and References

These are a typed copy of Lecture 23 from a series of handwritten lecture notes for the class Group Theory and Linear Algebra given on September 14, 2011.

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