Parabolic subgroup orbits on finite root systems

Oshima's Lemma describes the orbits of parabolic subgroups of irreducible finite Weyl groups on crystallographic root systems. This note generalises that result to all root systems of finite Coxeter groups, and provides a self contained proof, independent of the representation theory of semisimple complex Lie algebras

Geometry of certain finite Coxeter group actions

We determine a fundamental domain for the diagonal action of a finite Coxeter group $W$ on $V^{\oplus n}$, where $V$ is the reflection representation. This is used to give a stratification of $V^{\oplus n}$, which is respected by the group action, and we study the geometry, topology and combinatorics of this stratification. These ideas are used to obtain results on the classification of root subsystems up to conjugacy, as well as a character formula for $W$

Reflection subgroups of finite and affine Weyl groups

We discuss the classification of reflection subgroups of finite and affine Weyl groups from the point of view of their root systems. A short case free proof is given of the well known classification of the isomorphism classes of reflection subgroups using completed Dynkin diagrams, for which there seems to be no convenient source in the literature. This is used as a basis for treating the affine case, where finer classifications of reflection subgroups are given, and combinatorial aspects of root systems are shown to appear. Various parameter sets for certain types of subsets of roots are interpreted in terms of alcove geometry and the Tits cone, and combinatorial identities are derived

Quantum group actions on rings and equivariant K-theory

Let \Uq be a quantum group. Regarding a (noncommutative) space with \Uq-symmetry as a \Uq-module algebra $A$, we may think of equivariant vector bundles on $A$ as projective $A$-modules with compatible \Uq-action. We construct an equivariant K-theory of such quantum vector bundles using Quillen's exact categories, and provide means for its compution. The equivariant K-groups of quantum homogeneous spaces and quantum symmetric algebras of classical type are computed.Comment: 31 page

The first fundamental theorem of invariant theory for the orthosymplectic super group

We give a new proof, inspired by an argument of Atiyah, Bott and Patodi, of the first fundamental theorem of invariant theory for the orthosymplectic super group. We treat in a similar way the case of the periplectic super group. Lastly, the same method is used to explain the fact that Sergeev's super Pfaffian, an invariant for the special orthosymplectic super group, is polynomial

First fundamental theorems of invariant theory for quantum supergroups

Let $U_q(\mathfrak{g})$ be the quantum supergroup of $\mathfrak{gl}_{m|n}$ or the modified quantum supergroup of $osp_{m|2n}$ over the field of rational functions in $q$, and let $V_q$ be the natural module for $U_q(\mathfrak{g})$. There exists a unique tensor functor, associated with $V_q$, from the category of ribbon graphs to the category of finite dimensional representations of $U_q(\mathfrak{g}$, which preserves ribbon category structures. We show that this functor is full in the cases $\mathfrak{g}=\mathfrak{gl}_{m|n}$ or $osp_{2\ell+1|2n}$. For $\mathfrak{g}=osp_{2\ell|2n}$, we show that the space $Hom_{U_q(\mathfrak{g}}(V_q^{\otimes r}, V_q^{\otimes s})$ is spanned by images of ribbon graphs if $r+s< 2\ell(2n+1)$. The proofs involve an equivalence of module categories for two versions of the quantisation of $U(\mathfrak{g})$

The second fundamental theorem of invariant theory for the orthosymplectic supergroup

In a previous work we established a super Schur-Weyl-Brauer duality between the orthosymplectic supergroup of superdimension $(m|2n)$ and the Brauer algebra with parameter $m-2n$. This led to a proof of the first fundamental theorem of invariant theory, using some elementary algebraic supergeometry, and based upon an idea of Atiyah. In this work we use the same circle of ideas to prove the second fundamental theorem for the orthosymplectic supergroup. The proof uses algebraic supergeometry to reduce the problem to the case of the general linear supergroup, which is understood. The main result has a succinct formulation in terms of Brauer diagrams. Our proof includes new proofs of the corresponding second fundamental theorems for the classical orthogonal and symplectic groups, as well as their quantum analogues. These new proofs are independent of the Capelli identities, which are replaced by algebraic geometric arguments.Comment: 24 pages, 8 figure

Cellularity of certain quantum endomorphism algebras

We exhibit for all positive integers r, an explicit cellular structure for the endomorphism algebra of the r'th tensor power of an integral form of the Weyl module with highest weight d of the quantised enveloping algebra of sl2. When q is specialised to a root of unity of order bigger than d, we consider the corresponding specialisation of the tensor power. We prove one general result which gives sufficient conditions for the commutativity of specialisation with the taking of endomorphism algebras, and another which relates the multiplicities of indecomposable summands to the dimensions of simple modules for an endomorphism algebra. Our cellularity result then allows us to prove that knowledge of the dimensions of the simple modules of the specialised cellular algebra above is equivalent to knowledge of the weight multiplicities of the tilting modules for the specialised quantum group. In the final section we independently determine the weight multiplicities of indecomposable tilting modules for quantum sl2, and the decomposition numbers of the endomorphism algebras. We indicate how either one of these sets of numbers determines the other.Comment: 20 pages, 5 figure

Invariants of the orthosymplectic Lie superalgebra and super Pfaffians

Given a complex orthosymplectic superspace $V$, the orthosymplectic Lie superalgebra $\mathfrak {osp}(V)$ and general linear algebra ${\mathfrak {gl}}_N$ both act naturally on the coordinate super-ring $\mathcal{S}(N)$ of the dual space of $V\otimes{\mathbb C}^N$, and their actions commute. Hence the subalgebra $\mathcal{S}(N)^{\mathfrak {osp}(V)}$ of $\mathfrak {osp}(V)$-invariants in $\mathcal{S}(N)$ has a ${\mathfrak {gl}}_N$-module structure. We introduce the space of super Pfaffians as a simple ${\mathfrak {gl}}_N$-submodule of $\mathcal{S}(N)^{\mathfrak {osp}(V)}$, give an explicit formula for its highest weight vector, and show that the super Pfaffians and the elementary (or `Brauer') ${\rm OSp}$-invariants together generate $\mathcal{S}(N)^{\mathfrak {osp}(V)}$ as an algebra. The decomposition of $\mathcal{S}(N)^{\mathfrak {osp}(V)}$ as a direct sum of simple ${\mathfrak {gl}}_N$-submodules is obtained and shown to be multiplicity free. Using Howe's $({\mathfrak {gl}}(V), {\mathfrak {gl}}_N)$-duality on $\mathcal{S}(N)$, we deduce from the decomposition that the subspace of $\mathfrak{osp}(V)$-invariants in any simple ${\mathfrak {gl}}(V)$-tensor module is either $0$ or $1$-dimensional. These results also enable us to determine the $\mathfrak {osp}(V)$-invariants in the tensor powers $V^{\otimes r}$ for all $r$

A Temperley-Lieb analogue for the BMW algebra

The Temperley-Lieb algebra may be thought of as a quotient of the Hecke algebra of type A, acting on tensor space as the commutant of the usual action of quantum sl(2) on the n-th tensor power of the 2-dimensional irreducible module. We define and study a quotient of the Birman-Wenzl-Murakami algebra, which plays an analogous role for the 3-dimensional representation of quantum sl(2). In the course of the discussion we prove some general results about the radical of a cellular algebra, which may be of independent interest.Comment: 31 page