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==(1)==
 
==(1)==
 
Suppose that G is a group and that the set {x ∈ G | |x| = 2} has exactly one element. Show that G is abelian.  
 
Suppose that G is a group and that the set {x ∈ G | |x| = 2} has exactly one element. Show that G is abelian.  
 +
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.
 
----
 
----
 
==2==
 
==2==
 
You are given that G is group of order 24 which is not isomorphic to S4 .  
 
You are given that G is group of order 24 which is not isomorphic to S4 .  
 
Show that one of its Sylow subgroups is normal.  
 
Show that one of its Sylow subgroups is normal.  
 +
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.
 
----
 
----
 
==3==
 
==3==
Determine the number of pairwise non-isomorphic groups of order pq,  
+
Determine the number of pairwise non-isomorphic groups of order pq, where p and q are prime.
where p and q are prime.  
+
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.
 
----
 
----
 
==4==
 
==4==
Let ϕ : G  
+
Let ϕ : G → H be a homomorphism of groups. Let G # and H # denote  
→ H be a homomorphism of groups. Let G  
+
#  
+
and H # denote  
+
 
the set of conjugacy classes in G and H , respectively.  
 
the set of conjugacy classes in G and H , respectively.  
(a) Show that ϕ induces a map ϕ# : G#  
+
 
→ H  
+
(a) Show that ϕ induces a map ϕ# : G# → H#.  
#  
+
.  
+
  
 
(b) Show that if ϕ# is injective, so is ϕ.  
 
(b) Show that if ϕ# is injective, so is ϕ.  
  
 
(c) Show that if ϕ# is surjective, and H is finite, then ϕ is surjective. (Hint: one of the problems from PS1 might be useful here...)  
 
(c) Show that if ϕ# is surjective, and H is finite, then ϕ is surjective. (Hint: one of the problems from PS1 might be useful here...)  
 +
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.
 
----
 
----
 
==5==
 
==5==
Let G be a group of order 56 with a normal 2-Sylow subgroup Q, and let  
+
Let G be a group of order 56 with a normal 2-Sylow subgroup Q, and let P be a 7-Sylow subgroup of G. Show that G∼= P × Q or Q ∼= Z × Z × Z.
P be a 7-Sylow subgroup of G. Show that G
+
*Post link to solution/discussion page here
= P × Q or Q ∼= Z × Z × Z.  
+
*post link to other solution/discussion page here.
 
----
 
----
 
==6==
 
==6==
 
Let G be a group and H a subgroup of G with finite index. Show that  
 
Let G be a group and H a subgroup of G with finite index. Show that  
there exists a normal subgroup N of G of finite index with N  
+
there exists a normal subgroup N of G of finite index with N ⊂ H.
⊂ H .  
+
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.  
 
----
 
----
 
==7==
 
==7==
Let G be a finite group and P a p-Sylow subgroup of G for some prime p.  
+
Let G be a finite group and P a p-Sylow subgroup of G for some prime p. (You may assume that p divides  
(You may assume that p divides  
+
|G|. I haven’t had enough coffee to think about the implications of the vacuous case...)  
|G|. I haven’t had enough coffee to think  
+
about the implications of the vacuous case...)  
+
  
(a) Assume p=2 and P is cyclic. Show that the normalizer and central-
+
(a) Assume p=2 and P is cyclic. Show that the normalizer and centralizer of P coincide.  
izer of P coincide.  
+
  
 
(b) Show that this may not hold if p = 2 but P is not cyclic.  
 
(b) Show that this may not hold if p = 2 but P is not cyclic.  
  
(c) Show that the first statement does not hold regardless of cyclicity if  
+
(c) Show that the first statement does not hold regardless of cyclicity if p ̸= 2.
p  
+
*Post link to solution/discussion page here
̸= 2.  
+
*post link to other solution/discussion page here.
 
----
 
----
 
==8==
 
==8==
Let G be a finite group and ϕ : G  
+
Let G be a finite group and ϕ : G → G a homomorphism. Show that ϕ(P )  
→ G a homomorphism. Show that ϕ(P )  
+
 
is a subgroup of P whenever P is a normal Sylow subgroup.  
 
is a subgroup of P whenever P is a normal Sylow subgroup.  
1
+
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.
 
----
 
----
 
==9==
 
==9==
(a) Find all simple groups of order 101.  
+
(a) Find all simple groups of order 101.  
  
 
(b) Find all simple groups of order 102.  
 
(b) Find all simple groups of order 102.  
  
 
(c) Find all groups of order 175.  
 
(c) Find all groups of order 175.  
----
+
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.----
 
==10==
 
==10==
Let p and q be primes such that p divides q − 1.  
+
Let p and q be primes such that p divides q − 1.  
  
(a) Show that there exists a group G with generators x and y and rela-
+
(a) Show that there exists a group G with generators x and y and relations
tions
+
 
xp  
 
xp  
 
2  
 
2  
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of G having order d.  
 
of G having order d.  
 
2
 
2
 +
*Post link to solution/discussion page here
 +
*post link to other solution/discussion page here.
 
----
 
----
 
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Latest revision as of 08:27, 12 June 2013


Assignment #2, 06.12.13: Group Theory II

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(1)

Suppose that G is a group and that the set {x ∈ G | |x| = 2} has exactly one element. Show that G is abelian.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

2

You are given that G is group of order 24 which is not isomorphic to S4 . Show that one of its Sylow subgroups is normal.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

3

Determine the number of pairwise non-isomorphic groups of order pq, where p and q are prime.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

4

Let ϕ : G → H be a homomorphism of groups. Let G # and H # denote the set of conjugacy classes in G and H , respectively.

(a) Show that ϕ induces a map ϕ# : G# → H#.

(b) Show that if ϕ# is injective, so is ϕ.

(c) Show that if ϕ# is surjective, and H is finite, then ϕ is surjective. (Hint: one of the problems from PS1 might be useful here...)

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

5

Let G be a group of order 56 with a normal 2-Sylow subgroup Q, and let P be a 7-Sylow subgroup of G. Show that G∼= P × Q or Q ∼= Z × Z × Z.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

6

Let G be a group and H a subgroup of G with finite index. Show that there exists a normal subgroup N of G of finite index with N ⊂ H.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

7

Let G be a finite group and P a p-Sylow subgroup of G for some prime p. (You may assume that p divides |G|. I haven’t had enough coffee to think about the implications of the vacuous case...)

(a) Assume p=2 and P is cyclic. Show that the normalizer and centralizer of P coincide.

(b) Show that this may not hold if p = 2 but P is not cyclic.

(c) Show that the first statement does not hold regardless of cyclicity if p ̸= 2.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

8

Let G be a finite group and ϕ : G → G a homomorphism. Show that ϕ(P ) is a subgroup of P whenever P is a normal Sylow subgroup.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

9

(a) Find all simple groups of order 101.

(b) Find all simple groups of order 102.

(c) Find all groups of order 175.

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.----

10

Let p and q be primes such that p divides q − 1.

(a) Show that there exists a group G with generators x and y and relations xp 2 = 1, yq = 1, xyx−1 = ya , where a is an integer not congruent to 1 mod q, but ap ∼= 1(mod q).

(b) Prove that the Sylow q-subgroup Sq ⊂ G is normal.

(c) Prove that G/Sq is cyclic; and deduce that G has a unique subgroup H of order pq.

(d) Prove that H is cyclic.

(e) Prove that any subgroup of G with order p is contained in H , hence is generated by xp and is contained in the center of G.

(f ) Prove that the center of G is the unique subgroup of G having order p.

(g) Prove that every proper subgroup of G is cyclic.

(h) For each positive divisor d of p2 q, determine the number of elements of G having order d. 2

  • Post link to solution/discussion page here
  • post link to other solution/discussion page here.

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