Superizations of Cahen-Wallach symmetric spaces and spin representations of the Heisenberg algebra

Abstract

Let M0=G0/H be a (n+1)-dimensional Cahen-Wallach Lorentzian symmetric space associated with a symmetric decomposition g0=h+m and let S(M0) be the spin bundle defined by the spin representation r:H->GLR(S) of the stabilizer H. This article studies the superizations of M0, i.e. its extensions to a homogeneous supermanifold M=G/H whose sheaf of superfunctions is isomorphic to Lambda(S*(M0)). Here G is a Lie supergroup which is the superization of the Lie group G0 associated with a certain extension of the Lie algebra g0 to a Lie superalgebra g=g0+g1=g0+S, via the Kostant construction. The construction of the superization g consists of two steps: extending the spin representation r:h->glR(S) to a representation r:g0->glR(S) and constructing appropriate r(g0)-equivariant bilinear maps on S. Since the Heisenberg algebra heis is a codimension one ideal of the Cahen-Wallach Lie algebra g0, first we describe spin representations of gheis and then determine their extensions to g0. There are two large classes of spin representations of gheis and g0: the zero charge and the non-zero charge ones. The description strongly depends on the dimension n+1 (mod 8). Some general results about superizations g=g0+g1 are stated and examples are constructed.