Talk on BGG resolution
overview
- Weyl character formula and characters of Verma modules
- property of character map on short exact sequences
- Euler-Poincare mapping
- principal block : filtering through central characters
- is a block a $U(\mathfrak{g})$-submodule? yes
- how to check that it preserves the exactness : any homomorphism between modules belonging to different blocks will be zero
- combinatorial results
- consider the set of sum of k distinct roots. Which elements are linked to $0$?
- Bruhat ordering
- Bruhat ordering and strong linkage relation
- let $\lambda \in \Lambda^+$ (which is regular for the dot-action of $W$)
- $w'\cdot \lambda< w \cdot \lambda $ translates into $w < w'$ in the Bruhat ordering
- strong linkage relation and extension of Verma modules
characters
- let $\lambda\in \mathfrak{h}^*$
$$ \operatorname{ch} M({\lambda})=\frac{e^{\lambda}}{\prod_{\alpha>0}(1-e^{-\alpha})} $$
- let $\lambda\in \Lambda^+$
- thm (Weyl character formula)
\[ \operatorname{ch}L({\lambda})=\frac{\sum_{w\in W} (-1)^{\ell(w)}e^{w\cdot \lambda}}{\prod_{\alpha>0}(1-e^{-\alpha})} \]
- thus we have
$$ \operatorname{ch}L(\lambda)=\sum_{w \in W}(-1)^{\ell(w)}\operatorname{ch} M(w\cdot \lambda) \label{WCF} $$
- prop
If $0\to M' \to M \to M \to 0$ is a short exact sequence in $\mathcal{O}$, we have $$ \operatorname{ch}M=\operatorname{ch}M'+\operatorname{ch}M'' $$ or $$ \operatorname{ch}M'-\operatorname{ch}M+\operatorname{ch}M''=0 $$
- if we have a long exact sequence, we still get a similar alternating sum = 0 (why? Euler-Poincare mapping)
- goal : realize the alternating sum \ref{WCF} as an Euler characteristic of a suitable resolution of $L(\lambda)$
- The BGG resolution resolves a finite-dimensional simple $\mathfrak{g}$-module $L(\lambda)$ by direct sums of Verma modules indexed by weights "of the same length" in the orbit $W\cdot \lambda$
- thm (Bernstein-Gelfand-Gelfand Resolution)
Fix $\lambda\in \Lambda^{+}$. There is an exact sequence of Verma modules $$ 0 \to M({w_0\cdot \lambda})\to \cdots \to \bigoplus_{w\in W, \ell(w)=k}M({w\cdot \lambda})\to \cdots M({\lambda})\to L({\lambda})\to 0 $$ where $\ell(w)$ is the length of the Weyl group element $w$, $w_0$ is the Weyl group element of maximal length. Here $\rho$ is half the sum of the positive roots.
example of BGG resolution
$\mathfrak{sl}_2$
- \(L({\lambda})\) : irreducible highest weight module
- \(M({\lambda})\) : Verma modules
- note that the Verma modules are free modules of rank 1 over \(\mathbb{C}[F]\) where $F$ is the annihilation operator of $\mathfrak{sl}_2$
- \(\lambda ,-2+\lambda ,\cdots, -\lambda, -\lambda-2,\cdots\)
- \(L({\lambda})=M({\lambda})/M({-\lambda-2})\)
- BGG resolution
\[0\to M({-\lambda-2})\to M({\lambda})\to L({\lambda})\to 0\]
- number of modules = 2 (=order of Weyl group in general)
- character of $L({\lambda})$ = alternating sum of characters of Verma modules
\[\operatorname{ch}{L({\lambda})}=\operatorname{ch}{M({\lambda})}-\operatorname{ch}{M({-\lambda-2})}=\frac{q^{\lambda}}{1-q^{-2}}-\frac{q^{-\lambda-2}}{1-q^{-2}}\]
- comparison with Weyl-Kac character formula
\[\operatorname{ch} L({\lambda})=\frac{\sum_{w\in W} (-1)^{\ell(w)}e^{w(\lambda+\rho)}}{e^{\rho}\prod_{\alpha>0}(1-e^{-\alpha})}=\frac{q^{\lambda+1}-q^{-\lambda-1}}{q^{1}(1-q^{-2})}\] where \(\rho=1,\alpha=2\) and \(w(\lambda+\rho)=-\lambda-\rho\)
$\mathfrak{sl}_3$
weak BGG resolution
- def
- We say that $M \in O$ has a standard filtration (also called a Verma flag) if there is a sequence of submodules
$$0 = M_0 \subset M_1 \subset M_2 \subset \cdots \subset M_n = M$$ for which each $M^i := M_i/M_{i−1}\, (1 \le i \le n)$ is isomorphic to a Verma module.
- thm (Weak BGG resolution)
There is an exact sequence $$ 0 \to M({w_0\cdot \lambda}) = D_m^{\lambda} \to D_{m-1}^{\lambda} \to \cdots \to D_1^{\lambda} \to D_0^{\lambda}=M(\lambda) \to L(\lambda) \to 0 $$ where $D_{k}^{\lambda}$ has a standard filtration involving exactly once each of the Verma modules $M(w\cdot \lambda)$ with $\ell(w)=k$
strategy of the proof
- construct a relative version of standard resoultion $D_k:=U(\mathfrak{g})\otimes_{U(\mathfrak{b})}\Lambda^{k}(\mathfrak{g}/\mathfrak{b})$ for $\lambda=0$
- construct a weak BGG resolution $D_k^0:=D_k^{\chi_{0}}$ for $\lambda=0$ by cutting down to the principal block component of each term
- construct a weak BGG resolution $D_k^\lambda : = (D_k^0\otimes L(\lambda))^{\chi_{\lambda}}$ for $\lambda\in \Lambda^+$ by applying the translation functor
- show that it is actually a BGG resolution by computing $\operatorname{Ext}$ between Verma modules
standard resolution of trivial module
- free $U(\mathfrak{g})$-modules $U(\mathfrak{g})\otimes_{\mathbb{C}}\Lambda^{k}(\mathfrak{g})$
- standard resolution of trivial module
$$\cdots \to U(\mathfrak{g})\otimes_{\mathbb{C}}\Lambda^{k}(\mathfrak{g})\to U(\mathfrak{g})\otimes_{\mathbb{C}}\Lambda^{k-1}(\mathfrak{g})\to \cdots \to U(\mathfrak{g})\otimes_{\mathbb{C}}\Lambda^{0}(\mathfrak{g})\to L(0)$$
- the sequence of modules $D_k:=U(\mathfrak{g})\otimes_{U(\mathfrak{b})}\Lambda^{k}(\mathfrak{g}/\mathfrak{b})$ is a relative version of the standard resolution of the trivial module in Lie algebra cohomology
- $D_k$ are free only over $U(\mathfrak{n}^{−})$
- show that it is actually a complex and exact
- define $\partial_k : D_k \to D_{k-1}$ as
$$ \partial_k ( u\otimes \xi_1 \wedge \cdots \xi _k): = \sum_{i=1}^k(-1)^{i+1}(uz_i\otimes \xi_1\wedge \cdots \hat{\xi_i}\wedge \cdots \xi_k)+\sum_{1\le i<j \le k} (-1)^{i+j}(u \otimes \overline{[z_iz_j]} \xi_1\wedge \cdots \hat{\xi_i}\wedge \cdots \hat{\xi_j} \cdots \xi_k) $$
weights of exterior powers
- what are the weights of $\wedge^k (\mathfrak{g}/\mathfrak{b})$ as $\mathfrak{b}$-module?
- let $\beta$ be a sum of $k$-distinct negative root. Can we find $w\in W$ such that $w\cdot 0=\beta$?
- note that $|W\cdot 0|=|W|$
- yes, if and only if $\beta$ is a sum of elements in $w \Phi^+ \cap \Phi^-$
- now we have found the principal block $D_k^0$
tensor with simple module
- Remark in 6.2
- study $D_k^\lambda : = (D_k^0\otimes L(\lambda))^{\chi_{\lambda}}$
- first, find all Verma modules involved in a standard filtration of $D_k^0\otimes L(\lambda)$ : $w\cdot 0 + \mu$
- then determine which Verma modules are linked to $w\cdot \lambda$ : $\mu = w\lambda$
extensions of Verma modules
- $\mu, \lambda\in \mathfrak{h}^{*}$
- $\mu \uparrow \lambda$ if $\mu = \lambda$ or there is a root $\alpha$ such that $\mu=s_{\alpha}\cdot \lambda < \lambda $
- we say $\mu$ is strongly linked to $\lambda$ if $\mu = \lambda$ or there exist root $\alpha_1,\cdots, \alpha_r\in \Phi^+$ such that $\mu=(s_{\alpha_1}\cdots s_{\alpha_r})\cdot \lambda \uparrow (s_{\alpha_2}\cdots s_{\alpha_r})\cdot \lambda \uparrow ( s_{\alpha_r})\cdot \lambda \uparrow \cdots \uparrow \lambda $
- thm
Let $\lambda\in \mathfrak{h}^{*}$.
(a) If $\operatorname{Ext}_{\mathcal{O}}(M(\mu),M(\lambda))\neq 0$ for $\mu\in \mathfrak{h}^{*}$, then $\mu \uparrow \lambda$ but $\mu \neq \lambda$
(b) Let $\lambda\in \Lambda^{+}$ and $w,w'\in W$. If $\operatorname{Ext}_{\mathcal{O}}(M(w'\cdot\lambda),M(w\cdot\lambda))\neq 0$, then $w<w'$ in the Bruhat ordering. In particular, $\ell(w)<\ell(w')$.
- prop (3.7)
Let $M\in \mathcal{O}$ have a standard filtration. If $\lambda$ is maximal among the weights of $M$, then $M$ has a submodule isomorphic to $M(\lambda)$ and $M/M(\lambda)$ has a standard filtration.