# Difference between revisions of "Quiz:Symmetric group:S3"

See symmetric group:S3. We take the symmetric group on the set $\{ 1,2,3 \}$ of size three.

## Elements

See element structure of symmetric group:S3 for full details.

### Element orders and conjugacy class structure

1 What is the number of non-identity elements of the symmetric group of degree three?

 2 3 4 5 6

2 How many elements are there of order exactly three in the symmetric group of degree three?

 2 3 4 5 6

3 Which of the following is a correct description of the conjugacy class structure of the symmetric group of degree three?

 Conjugacy class of size 1 and order (of elements in the conjugacy class) 1, conjugacy class of size 2 and order (of elements in the conjugacy class) 2, conjugacy class of size 3 and order (of elements in the conjugacy class) 3 Conjugacy class of size 1 and order (of elements in the conjugacy class) 1, conjugacy class of size 2 and order (of elements in the conjugacy class) 3, conjugacy class of size 3 and order (of elements in the conjugacy class) 2 Conjugacy class of size 1 and order (of elements in the conjugacy class) 2, conjugacy class of size 2 and order (of elements in the conjugacy class) 1, conjugacy class of size 3 and order (of elements in the conjugacy class) 3 Conjugacy class of size 1 and order (of elements in the conjugacy class) 2, conjugacy class of size 2 and order (of elements in the conjugacy class) 3, conjugacy class of size 3 and order (of elements in the conjugacy class) 1 Conjugacy class of size 1 and order (of elements in the conjugacy class) 3, conjugacy class of size 2 and order (of elements in the conjugacy class) 1, conjugacy class of size 3 and order (of elements in the conjugacy class) 2 Conjugacy class of size 1 and order (of elements in the conjugacy class) 3, conjugacy class of size 2 and order (of elements in the conjugacy class) 2, conjugacy class of size 3 and order (of elements in the conjugacy class) 1

### Multiplication, conjugacy and generating sets

1 What can we say about the order of the product of two distinct elements, each of order exactly two, in the symmetric group of degree three?

 The product must be the identity element The product must have order two The product can have order either 1 or 2 The product must have order three The product can have order either 1 or 3

2 What can we say about the order of the product of two distinct elements, each of order exactly three, in the symmetric group of degree three?

 The product must be the identity element The product must have order two The product can have order either 1 or 2 The product must have order three The product can have order either 1 or 3

3 Which of the following is false in the symmetric group of degree three?

 Any two elements of the same order are conjugate Every element is conjugate to its inverse Any two elements generating the same cyclic subgroup are conjugate Any two elements that together generate the whole group are conjugate None of the above, i.e., they are all true

### Conjugation and commutator operations

1 Suppose $g$ and $h$ are distinct elements of order two in the symmetric group of order three. What can we say about $ghg^{-1}$ (this is a conjugate of $h$ by $g$)?

 It equals $g$ It equals $h$ It equals an element of order two that is neither $g$ nor $h$ It is an element of order three It is the identity element

2 Suppose $g$ and $h$ are distinct elements of order two in the symmetric group of order three. What can we say about the commutator $ghg^{-1}h^{-1}$?

 It equals $g$ It equals $h$ It equals an element of order two that is neither $g$ nor $h$ It is an element of order three It is the identity element

3 Suppose $g$ and $h$ are distinct elements of order three in the symmetric group of order three. What can we say about $ghg^{-1}$ (this is a conjugate of $h$ by $g$)?

 It equals $g$ It equals $h$ It equals an element of order two It is the identity element

4 Suppose $g$ and $h$ are distinct elements of order three in the symmetric group of order three. What can we say about the commutator $ghg^{-1}h^{-1}$?

 It equals $g$ It equals $h$ It is an element of order two It is the identity element

5 Suppose $g$ is an element of order two and $h$ is an element of order three in the symmetric group of order three. What are the orders of the elements $ghg^{-1}$ and $hgh^{-1}$ respectively?

 1 and 1 2 and 3 3 and 2 2 and 2 3 and 3