Groups Exercises I

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

Department of Mathematics
University of Wisconsin, Madison
Madison, WI 53706 USA
ram@math.wisc.edu

Last updates: 9 February 2010

Groups Exercises I

Show that the intersection of two subgroups of a group $G$ is a subgroup of $G .$
Give an example which shows that the union of two subgroups of a group $G$ need not be a subgroup of $G .$
Let $G$ be a group and let $H$ and $K$ be two subgroups of $G .$ Assume that $H ⊈ K$ and that $K ⊈ H .$ Show that $H \cup K$ is not a subgroup of $G .$

2. Let $G$ be a group and let $S$ be a subgroup of $G .$ Let $ℋ$ be the set of subgroups $H$ of $G$ such that $S \subseteq H .$ Define $H_{S} = ⋂_{H \in ℋ} H .$

Show that, by the preceding exercise, $H_{S}$ is a subgroup of $G .$
Show that $S \subseteq H_{S}$ since $S \subseteq H$ for every $H \in ℋ .$
Show that if $H$ is a subgroup of $G$ and $S \subseteq H$ then $H \supseteq H_{S} .$

Conclude that

H_{S} = ⟨S⟩ .

⟨S⟩

is the smallest subgroup of

G

containing

S .

3. Lagrange's Theorem Let $G$ be a group and let $H$ and $K$ be subgroups of $G$ with $K \subseteq H \subseteq G .$ Show that $|G : K| = |G : H| |H : K| .$

Show that Corollary 2.3 is a special case of the theorem with $K = (1) .$

4. Let $G$ be a group and let $H$ be a subgroup of $G .$ A double coset of $H$ in $G$ is a set $H g H = \{h g h' | h, h' \in H\},$ where $g \in G .$ The notation $H \ G / H$ denotes the set of double cosets of $H$ in $G .$

Show that the double cosets of $H$ in $G$ partition $G .$

5. Let $f : G \to H$ be a group homomorphism.

a) Let $M \subseteq G$ be a subgroup of $G$ and define $f (M) = \{f (m) | m \in M\} .$

Show that $f (M)$ is a subgroup of $H .$
Show that $f (M) \subseteq im f = f (G) .$
Show that if $f$ is surjective and $M$ is a normal subgroup of $G$ then $f (M)$ is a normal subgroup of $H .$
Gve an example of a homomorphism $f : G \to H$ and of a normal subgroup $M$ of $G$ such that $f (M)$ is not a normal subgroup of $H .$

$\begin{array}{rcl} G & \overset{f}{\to} & H \\ M & \mapsto & f (M) \\ \cap | & \cap | \\ G & \mapsto & f (G) = im f . \end{array}$

b) Let $N \subseteq H$ be a subgroup of $H$ and define $f^{- 1} (N) = \{g \in G | f (g) \in N\} .$

Show that $f^{- 1} (N)$ is a subgroup of $G .$
Show that $f^{- 1} (N) \supseteq \ker f = f^{- 1} (1) .$
Show that if $N$ is a normal subgroup of $H$ then $f^{- 1} (N)$ is a normal subgroup of $G .$

$\begin{array}{rcl} G & \overset{f}{\to} & H \\ f^{- 1} (N) & \mapsto & N \\ \cup | & \cup | \\ \ker f = f^{- 1} (1) & \mapsto & (1) . \end{array}$

Let $M$ be a subgroup of $G$ and show that $M \subseteq f^{- 1} (f (M)) .$
Give an example of a homomorphism $f : G \to H$ and a subgroup $M$ of $G$ such that $M \neq f^{- 1} (f (M)) .$
Show that if $M \subseteq G$ is a subgroup of $G$ that contains $\ker f$ then $M = f^{- 1} (f (M)) .$

Let $N$ be a subgroup of $H$ and show that $N \supseteq f (f^{- 1} (N)) .$
Give an example of a homomorphism $f : G \to H$ and a subgroup $N$ of $H$ such that $N \neq f (f^{- 1} (N)) .$
Show that if $N \subseteq H$ is a subgroup of $H$ and $N \subseteq im f$ then $N = f^{- 1} (f (N)) .$

Conclude from c) and d) that there is a one-to-one correspondence between subgroups of $G$ that contain $\ker f$ and subgroups of $H$ that are contained in $im f .$
Give an example to show that this correspondence does not necessarily take normal subgroups to mormal subgroups.
Show that if $f$ is surjective then this correspondence takes normal subgroups of $G$ to normal subgroups of $H .$

Let $H$ be a subgroup of a group $G .$ The canonical injection is the map $i : H \to G$ given by $\begin{array}{rcl} i : & G & \to & H \\ h & \mapsto & h . \end{array}$

i : H \to G

Let $N$ be a normal subgroup of a group $G .$ The canonical surjection or canonical projection is the map given by $\begin{array}{rcl} π : & G & \to & G / N \\ g & \mapsto & g N . \end{array}$

π : G \to G / N

im π = G / N

\ker π = N .

Let $M$ be a subgroup of $G .$ Show, using Ex 1.1.5 that
$M / N = \{m N | m \in M\}$ is a subgroup of $G / N .$
$M / N$ is a normal subgroup of $G / N$ if $M$ is a normal subgroup of $G .$
$M / N = π (M)$ and if $M$ contains $N$ then $π^{- 1} (π (M)) = M .$
Conclude that there is a one-to-one correspondence between subgroups of $G$ containing $N$ and subgroups of $G / N .$
Show that this correspondence takes normal subgroups to normal subgroups.

7. An exact sequence $\dots \to G_{i - 1} \overset{f_{i - 1}}{\to} G_{i} \overset{f_{i}}{\to} G_{i + 1} \to \dots$ is a sequence of groups and group homomorphisms $f_{i} : G_{i} \to G_{i + 1}$ such that $\ker f_{i} = im f_{i - 1}$ for all $i .$

A short exact sequence is an exact sequence of the form $(1) \to K \overset{g}{\to} G \overset{f}{\to} H \to (1) .$

Show that in the above hort exact seqience $g$ is always injective and $f is always surjective.$
Let $f : G \to H$ be a group homomorphism and show that the sequence $(1) \to \ker f \to G \to im f \to (1)$ is always exact.
Let $K$ be a normal subgroup of a group $G .$ Let $i : K \to G$ be the canonical injection and let $π : G \to G / K$ be the canonical surjection. Show that $(1) \to K \overset{i}{\to} G \overset{π}{\to} G / K \to (1)$ is a short exact sequence.

8. Let $N$ be a normal subgroup of a group $G .$ Let $K$ be a normal subgroup of $G$ containing $N .$ Then, by Ex 1.1.6 c)ii), $K / N = \{k N | k \in K\}$ is a normal subgroup of $G / N .$ Let $\frac{G / N}{K / N}$ be the quotient group and let $π_{2} : G / N \to \frac{G / N}{K / N}$ be the canonical projection.

Let $π_{1} : G \to G / N$ be the canonical projection so that $(π_{1} \circ π_{2}) : G \overset{π_{1}}{\to} G / N \overset{π_{2}}{\to} \frac{G / N}{K / N} .$

Show that $im (π_{1} \circ π_{2}) = \frac{G / N}{K / N} .$
Show that $\ker (π_{1} \circ π_{2}) = K .$
Using Theorem 2.4 b) conclude that $G / K ≃ \frac{G / N}{K / N}$ as groups.

Prove that if $H$ and $K$ are subgroups of a group $G$ then $H K = \{h k | h \in H, k \in K\}$ is a subgroup of $G$ if al least one of $H$ and $K$ is normal in $G .$
Prove that if $H$ and $K$ are subgroups of a group $G$ and $K$ is normal in $G$ then the subgroup $⟨H, K⟩ = H K .$ Warning! Don't even think that $|H| |K| = |H K| .$
Give an example of subgroups $H$ and $K$ of a group $G$ such that $K$ is normal and $|H| |K| \neq |H K| .$

10. Let $K$ be a normal subgroup of a group $G$ and let $H$ be any subgroup of $G .$ Let $\begin{array}{rcl} π : & H & \to & G / K \\ h & \mapsto & h K \end{array}$ be the restriction of the canonical surjection $π : G \to G / K$ to $H .$

Show that $\ker π = H \cap K .$
Show that $im π = \frac{H K}{K} = \{h K | h \in H\} .$
Using Theorem 2.4 b), conclude that $\frac{H}{H \cap K} ≃ \frac{H K}{K} .$

11. Let $H_{1}$ and $H_{2}$ be subgroups of groups $G_{1}$ and $G_{2}$ respectively.

Show that $H_{1} \times H_{2}$ is a subgroup of $G_{1} \times G_{2} .$
Let $π_{1} : G_{1} \to G_{1} / H_{1}$ and $π_{2} : G_{2} \to G_{2} / H_{2}$ be the canonical projections. Define a map $\begin{array}{rcl} (π_{1} \times π_{2}) : & G_{1} \times G_{2} & \to & G_{1} / H_{1} \times G_{2} / H_{2} \\ (g_{1}, g_{2}) & \mapsto & (g_{1} H_{1}, g_{2} H_{2}) . \end{array}$ Show that $π_{1} \times π_{2}$ is a well defined surjective group homomorphism.
Show that $\ker (π_{1} \times π_{2}) = H_{1} \times H_{2} .$
Using Theorem 2.4 b), conclude that $\frac{G_{1} \times G_{2}}{H_{1} \times H_{2}} ≃ \frac{G_{1}}{H_{1}} \times \frac{G_{2}}{H_{2}} .$

References [PLACEHOLDER]

[BG] A. Braverman and D. Gaitsgory, Crystals via the affine Grassmanian, Duke Math. J. 107 no. 3, (2001), 561-575; arXiv:math/9909077v2, MR1828302 (2002e:20083)

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