Spectral Properties of Harmonic Toeplitz Operators and Applications to the Perturbed Krein Laplacian

Abstract

We consider harmonic Toeplitz operators TV = PV: H() H() where P: L2() H() is the orthogonal projection onto H() = \u ∈ L2()\,|\, u = 0 \; in\;\, ⊂ Rd, d ≥ 2, is a bounded domain with ∂ ∈ C∞, and V: C is a suitable multiplier. First, we complement the known criteria which guarantee that TV is in the pth Schatten-von Neumann class Sp, by sufficient conditions which imply TV ∈ Sp, w, the weak counterpart of Sp. Next, we assume that is the unit ball in Rd, and V = V is radially symmetric, and investigate the eigenvalue asymptotics of TV if V has a power-like decay at ∂ or V is compactly supported in . Further, we consider general and V ≥ 0 which is regular in , and admits a power-like decay of rate γ > 0 at ∂ , and we show that in this case TV is unitarily equivalent to a pseudo-differential operator of order -γ, self-adjoint in L2(∂ ). Using this unitary equivalence, we obtain the main asymptotic term of the eigenvalue counting function for the operator TV. Finally, we introduce the Krein Laplacian K ≥ 0, self-adjoint in L2(); it is known that Ker\,K = H(), and the zero eigenvalue of K is isolated. We perturb K by V ∈ C(; R), and show that σ ess(K+V) = V(∂ ). Assuming that V ≥ 0 and V|∂ = 0, we study the asymptotic distribution of the eigenvalues of K V near the origin, and find that the effective Hamiltonian which governs this distribution is the Toeplitz operator TV.