I´m working myself right now through this article and have trouble understanding a part of the proof of Proposition 6.4, case II) on page 345-346. I try to give a short outline of the situation:
Suppose $V$ is an irreducible $\mathfrak{g}$ module, with highest weight $\lambda$. And $\mathfrak{g}$ being a semisimple Lie-algebra, with a subalgebra $\mathfrak{s} \simeq \mathfrak{sl}(2,\mathbb{C})$. Also let $V$ be a complex vector space [Edit] that as an $\mathfrak{s}$-module is the direct sum $V=V(1)\oplus V_0$, where $V(1)$ is the usual 2-dimensional (irreducible) representation of $\mathfrak{s}$, and $V_0$ is a direct sum of trivial 1-dimensional representations of $\mathfrak{s}$ [/Edit, JL]. Then the statement i want to verify goes as follows:
Then there exists a dominant root $\alpha$ for $\mathfrak{g}$, s.th. $(\lambda, \alpha^{\lor})=1, (w_0 \lambda, \alpha^{\lor})=-1, (\mu, \alpha^{\lor})=0$ for all weights $\mu$ with $w_0 \lambda < \mu < \lambda$. Here $w_0$ is the longest element in the Weyl group $\mathfrak{W}$ , and $<$ the usual ordering.
My thoughts so far:
- By the theorem of the highest weight there exists a highest weight $\lambda$ satisfying $$2\frac{(\lambda, \alpha)}{(\alpha,\alpha)} \in \mathbb{Z},$$ which coincides with $(\lambda, \alpha^{\lor})$, using the definition of the coroot of a semisimple Lie-algebra.
- Using the Properties of the longest element $w_0$ in the Weyl-group of a semisimple Lie-algebra $\mathfrak{g}$ and concidering that $\mathfrak{sl}(n,\mathbb{C})$ has root system $A_{n-1}$, $w_0$ satisfies $w_0\lambda = - \lambda$. So in particular we have $$(w_0 \lambda, \alpha^{\lor}) = - (\lambda, \alpha^{\lor}).$$
- The trivial representation of $\mathfrak{s}$ has a single weight, $0$.
- Let $V(1)=\mathbb{C}^2$ be the standard representation. Write $e_1,e_2$ for the standard basis. Note that $$H=\begin{pmatrix} 1 & 0\\ 0 & -1\\ \end{pmatrix}.$$ Then $He_1 = e_1$ and $He_2 = -e_2$. Thus the set of weights of $V(1)$ is $\{\pm1\}$.
