Weyl Solutions and J-selfadjointness for Dirac operators

Abstract

We consider a non-selfadjoint Dirac-type differential expression equation D(Q)y:= Jn dydx + Q(x)y, (1) equation with a non-selfadjoint potential matrix Q ∈ L1loc( I,Cn× n) and a signature matrix Jn =-Jn-1 = -Jn*∈ Cn× n. Here I denotes either the line R or the half-line R+. With this differential expression one associates in L2( I,Cn) the (closed) maximal and minimal operators D(Q) and D(Q), respectively. One of our main results states that D(Q) = D(Q) in L2(R,Cn). Moreover, we show that if the minimal operator D(Q) in L2(R,Cn) is j-symmetric with respect to an appropriate involution j, then it is j-selfadjoint. Similar results are valid in the case of the semiaxis R+. In particular, we show that if n=2p and the minimal operator D(Q) in L2(R+,C2p) is j-symmetric, then there exists a 2p× p-Weyl-type matrix solution (z, ·)∈ L2(R+,C2p× p) of the equation D+(Q)(z, ·)= z(z, ·). A similar result is valid for the expression (1) with a potential matrix having a bounded imaginary part. This leads to the existence of a unique Weyl function for the expression (1). The differential expression (1) is of significance as it appears in the Lax formulation of the vector-valued nonlinear Schr\"odinger equation.