10-1100/Homework Assignment 2: Difference between revisions

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# (Selick)
# (Selick)
## What it the least integer <math>n</math> for which the symmetric group <math>S_n</math> contains an element of order 18?
## What it the least integer <math>n</math> for which the symmetric group <math>S_n</math> contains an element of order 18?
## What is the maximal order of an element in <math>S_{52}</math>? (That is, of a shuffling of a deck of cards?)
## What is the maximal order of an element in <math>S_{26}</math>? (That is, of a shuffling of the red cards within a deck of cards?)
# (Selick) Let <math>H</math> be a subgroup of index 2 in a group <math>G</math>. Show that <math>H</math> is normal in <math>G</math>.
# (Selick) Let <math>H</math> be a subgroup of index 2 in a group <math>G</math>. Show that <math>H</math> is normal in <math>G</math>.
# Let <math>\sigma\in S_{20}</math> be a permutation whose cycle decomposition consists of one 5-cycle, two 3-cycles, and one 2-cycle. What is the order of the centralizer <math>C_{S_{20}}(\sigma)</math> of <math>\sigma</math>?
# Let <math>\sigma\in S_{20}</math> be a permutation whose cycle decomposition consists of one 5-cycle, two 3-cycles, and one 2-cycle. What is the order of the centralizer <math>C_{S_{20}}(\sigma)</math> of <math>\sigma</math>?

Latest revision as of 12:29, 20 October 2010

This assignment is due at class time on Thursday, October 21, 2010.

Solve the following questions

  1. (Selick)
    1. What it the least integer for which the symmetric group contains an element of order 18?
    2. What is the maximal order of an element in ? (That is, of a shuffling of the red cards within a deck of cards?)
  2. (Selick) Let be a subgroup of index 2 in a group . Show that is normal in .
  3. Let be a permutation whose cycle decomposition consists of one 5-cycle, two 3-cycles, and one 2-cycle. What is the order of the centralizer of ?
  4. (Selick) Let be a group of odd order. Show that is not conjugate to unless .
  5. (Dummit and Foote) Show that if is cyclic then is Abelian.
  6. (Lang) Prove that if the group of automorphisms of a group is cyclic, then is Abelian.
  7. (Lang)
    1. Let be a group and let be a subgroup of finite index. Prove that there is a normal subgroup of , contained in , so that is also finite. (Hint: Let and find a morphism whose kernel is contained in .)
    2. Let be a group and and be subgroups of . Suppose and . Show that