Non-Local Matrix Generalizations of W-Algebras

Abstract

There is a standard way to define two symplectic (hamiltonian) structures, the first and second Gelfand-Dikii brackets, on the space of ordinary linear differential operators of order m, L = -dm + U1 dm-1 + U2 dm-2 + … + Um. In this paper, I consider in detail the case where the Uk are n× n-matrix-valued functions, with particular emphasis on the (more interesting) second Gelfand-Dikii bracket. Of particular interest is the reduction to the symplectic submanifold U1=0. This reduction gives rise to matrix generalizations of (the classical version of) the non-linear Wm-algebras, called Vm,n-algebras. The non-commutativity of the matrices leads to non-local terms in these Vm,n-algebras. I show that these algebras contain a conformal Virasoro subalgebra and that combinations Wk of the Uk can be formed that are n× n-matrices of conformally primary fields of spin k, in analogy with the scalar case n=1. In general however, the Vm,n-algebras have a much richer structure than the Wm-algebras as can be seen on the examples of the non-linear and non-local Poisson brackets of any two matrix elements of U2 or W3 which I work out explicitly for all m and n. A matrix Miura transformation is derived, mapping these complicated second Gelfand-Dikii brackets of the Uk to a set of much simpler Poisson brackets, providing the analogue of the free-field realization of the Wm-algebras.

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