Practicing for my upcoming exam and I have no idea how to do this:
Let $C_4$ be the cyclic group of order $4$ and $S_3$ the third symmetric group.
(a) Give an example of a homomorphism from $C_4$ to $S_3$ whose image contains more than just the identity element of $S_3$.
(b) Is it possible for such a homomorphism to be 1 to 1? Why or why not?
For (a), I know the subgroup of $Q = \{(), (1 2 3), (1 3 2)\}$ of $S_3$ is isomorphic to $C_3$ but I don't know how to make a homomorphism from $C_4$.
(a) you can consider the subgroup $C_2 = (12)$ of $S_3$ and the projection $\pi$ of $C_4$ on $C_2$ given by $\pi([n]_4) = [n]_2$.
(b) In order to find a contradiction, suppose that there is an injection of $C_4$ in $S_3$. This means that there is a copy of the cyclic group $C_4$ in $S_3$. But you can check by hand that this is false because there is no-element of $S_3$ with order bigger or equal to $4$.