Jacquet module and Frobenius reciprocity

Question

Let $F$ be a local field of characteristic zero and $G$ be a classical group over $F$.

Let $P=MN$ be a parabolic subgroup of $G$ and $\pi$ a irreducible smooth representation of $M$.

Let $\sigma$ be an irreducible constituent of normalized parabolic induction $\operatorname{Ind}_{M}^G(\pi)$. Then I am wondering whether the normalized Jacquet module $J_{N}(\sigma)$ has $\pi$ as a quotient? Some paper argues in this way without proof but I don't know the reason exactly. Why does it hold?

There is one more question. What is the difference of irreducible subquotient and irreducible consitituent of a module? I guess the people use the later when the given module is of finite length and the former is used in more general situations. Am I right?

Thank you very much!

Answer 1

In general, all we can say from "general abstract nonsense" is that if $\sigma$ is a subrepresentation of $Ind_P^G(\pi)$, then $\pi$ is a quotient of $J_N(\sigma)$; but you don't immediately get any further information about other composition factors.

However, if the $M$-representation $\pi$ is supercuspidal (which is usually the most interesting case) -- in particular, when $P$ is a Borel subgroup -- then we have the implications

"$\pi$ occurs as a subquotient of $J_N(\sigma)$" $\iff$ "$\pi$ occurs as a quotient of $J_N(\sigma)$" $\iff$ "$\pi$ occurs as a sub of $J_N(\sigma)$".

This is because supercuspidal $M$-representations are projective objects once you fix the central character.

The question about "constituent" vs "subquotient" seems to have been answered in the comments.