Imaginary Schur-Weyl duality for quiver Hecke superalgebras

Abstract

The irreducible modules over quiver Hecke superalgebras Rθ can be classified in terms of cuspidal modules. To an indivisible positive root α and a non-negative integer d, one associates a quotient Rdα of Rdα called the cuspidal algebra. If the root α is real, the cuspidal algebra is well-understood. But if α=δ, the imaginary null-root, the imaginary cuspidal algebra Rdδ is rather mysterious. It has been known that the number of the isomorphism classes of the irreducible Rdδ-modules equals the number of the -multipartitions of d, but there has been no way to canonically associate an irreducible Rdδ-module to such a multipartiton. The imaginary cuspidal algebra is especially important because of its connections to the RoCK blocks of the double covers of symmetric and alternating groups. We undertake a detailed study of the imaginary cuspidal algebra and its representation theory. We use the so-called Gelfand-Graev idempotents and subtle degree and parity shifts to construct a (graded) Morita (super)equivalent algebra C(n,d) (for any n≥ d). The advantage of the algebra C(n,d) is that, unlike Rdδ, it is non-negatively graded. Moreover, the degree zero component C(n,d)0 is shown to be isomorphic to the direct sum of tensor products of copies of the classical Schur algebras. This gives the classification (and the description of dimensions/characters, etc.) of the irreducible C(n,d)-modules, and hence of the irreducible Rdδ-modules, in terms of the classical Schur algebras. In particular, this allows us to canonically label these by the -multipartitions of d. The results of this paper will be used in our future work on RoCK blocks of the double covers of symmetric groups.

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