The first cohomology, derivations and the reductivity of a (meromorphic open-string) vertex algebra

Abstract

We give a criterion for the complete reducibility of modules satisfying a composability condition for a meromorphic open-string vertex algebra V using the first cohomology of the algebra. For a V-bimodule M, let H1∞(V, M) be the first cohomology of V with the coefficients in M. Let Z1∞(V, M) be the subspace of H1∞(V, M) canonically isomorphic to the space of derivations obtained from the zero mode of the right vertex operators of weight 1 elements such that the difference between the skew-symmetric opposite action of the left action and the right action on these elements are Laurent polynomials in the variable. If H1∞(V, M)= Z1∞(V, M) for every -graded V-bimodule M, then every left V-module satisfying a composability condition is completely reducible. In particular, since a lower-bounded -graded vertex algebra V is a special meromorphic open-string vertex algebra and left V-modules are in fact what has been called generalized V-modules with lower-bounded weights (or lower-bounded generalized V-modules), this result provides a cohomological criterion for the complete reducibility of lower-bounded generalized modules for such a vertex algebra. We conjecture that the converse of the main theorem above is also true. We also prove that when a grading-restricted vertex algebra V contains a subalgebra satisfying some familiar conditions, the composability condition for grading-restricted generalized V-modules always holds and we need H1∞(V, M)= Z1∞(V, M) only for every -graded V-bimodule M generated by a grading-restricted subspace in our complete reducibility theorem.