Show that for every 2 elements $\alpha$ and $\beta$ in $S_{8}$, the permutation $\alpha ^{-1}\beta ^{2}\alpha $ is an even permutation.
How do I show that the above is an even permutation? I know that permutations are always either even or dd and that even permutation forms a subgroup. But I'm stuck on this one.
Here Notice that ${\beta}^2$ is always even permutation.
Case-1 $\alpha$ even permutation
So ${\alpha}^{-1}$ is also even permutation and hence ${\alpha}^{-1}{\beta}^2\alpha$ is even permutation
Case-2 $\alpha$ odd permutation
So ${\alpha}^{-1}$ is also odd permutation and hence both $\alpha ~\&~{\alpha}^{-1}$ are product of odd number of transpositions and ${\beta}^2$ is product of even no. of transpositions.
So ${\alpha}^{-1}{\beta}^2\alpha$ is product of odd+even+odd=even no. of transpositions. And hence ${\alpha}^{-1}{\beta}^2\alpha$ is an even permutation.
You can prove it using $alternating~map$
$\psi ({\alpha}^{-1}{\beta}^2\alpha)=\psi(\alpha^{-1})~ \psi(\beta^2) ~\psi(\alpha)=(\psi(\beta))^2=1$
which also shows that ${\alpha}^{-1}{\beta}^2\alpha$ is an even permutation