English

Monotonicity and Concavity Properties of The Spectral Shift Function

Spectral Theory 2007-05-23 v1

Abstract

Let H0H_0 and V(s)V(s) be self-adjoint, V,VV,V' continuously differentiable in trace norm with V(s)0V''(s)\geq 0 for s(s1,s2)s\in (s_1,s_2), and denote by {EH(s)(λ)}λ\bbR\{E_{H(s)}(\lambda)\}_{\lambda\in\bbR} the family of spectral projections of H(s)=H0+V(s)H(s)=H_0+V(s). Then we prove for given μ\bbR\mu\in\bbR, that s\tr(V(s)EH(s)((,μ)))s\longmapsto \tr\big (V'(s)E_{H(s)}((-\infty, \mu))\big) is a nonincreasing function with respect to ss, extending a result of Birman and Solomyak. Moreover, denoting by ζ(μ,s)=μdλξ(λ,H0,H(s))\zeta (\mu,s)=\int_{-\infty}^\mu d\lambda \xi(\lambda,H_0,H(s)) the integrated spectral shift function for the pair (H0,H(s))(H_0,H(s)), we prove concavity of ζ(μ,s)\zeta (\mu,s) with respect to ss, extending previous results by Geisler, Kostrykin, and Schrader. Our proofs employ operator-valued Herglotz functions and establish the latter as an effective tool in this context.

Keywords

Cite

@article{arxiv.math/9909076,
  title  = {Monotonicity and Concavity Properties of The Spectral Shift Function},
  author = {F. Gesztesy and K. A. Makarov and A. K. Motovilov},
  journal= {arXiv preprint arXiv:math/9909076},
  year   = {2007}
}

Comments

LaTeX, 15 pages