Let $G$ be a classical groups (including $\operatorname U(n)$, $\operatorname{SO}(n)$, and $\operatorname{Sp}(2n)$), and $V$ be the defining representation (the natural inclusion of $G$ into $\operatorname{GL}(n,C)$). When are $S^kV$ and $\bigwedge\nolimits^kV$ irreducible ?
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1$\begingroup$ what are $S^kV$ and $\Lambda^k V$? Could you elaborate? $\endgroup$– vidyarthiCommented Nov 26, 2020 at 20:00
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2$\begingroup$ I assume V is the defining representation, and these are the symmetric and exterior powers. $\endgroup$– Sam HopkinsCommented Nov 26, 2020 at 20:09
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1 Answer
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You can find the decomposition of $S^kV$ and $\Lambda^k V$ into a direct sum of irreducible representations in Table 5 in the book: Onishchik and Vinberg, Lie Groups and Algebraic Groups, Springer-Verlag 1990.
Instead of $U(n)$ you can consider its complexification ${\rm GL}(n,{\Bbb C})$. Then both $S^k V$ and $\Lambda^k V$ are irreducible.
For ${\rm SO}(n)$, the representations $\Lambda^k V$ are irreducible for $k\neq n/2$, while $S^k V$ are reducible for all $k>1$ (indeed, for $k=2$ we know that $S^2 V$ contains the trivial representation).
For ${\rm Sp}(2n)$, the representations $S^k V$ are irreducible, while $\Lambda^k V$ are reducible for $1<k<2n-1$ (indeed, for $k=2$ we know that $\Lambda^2 V$ contains the trivial representation).
answered Nov 26, 2020 at 20:28