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The transition operator of a random walk perturbated by sparse potentials

Takuya Mine, Nobuo Yoshida

Abstract

We consider an operator $P_V=(1+V)P$ on $\ell^2(Z^d)$, where $P$ is the transition operator of a symmetric irreducible random walk, and $V$ is a ``sparse'' potential. We first characterize the essential spectra of this operator. Secondly, we prove that all the eigenfunctions which correspond to discrete spectra decay exponentially fast. Thirdly, we give a sufficient condition for this operator to have an absolute spectral gap at the right edge of the spectra. Finally, as an application of the absolute spectral gap and the exponential decay of the eigenfunctions, we prove a limit theorem for the random walk under the Gibbs measure associated to the potential $V$.

The transition operator of a random walk perturbated by sparse potentials

Abstract

We consider an operator on , where is the transition operator of a symmetric irreducible random walk, and is a ``sparse'' potential. We first characterize the essential spectra of this operator. Secondly, we prove that all the eigenfunctions which correspond to discrete spectra decay exponentially fast. Thirdly, we give a sufficient condition for this operator to have an absolute spectral gap at the right edge of the spectra. Finally, as an application of the absolute spectral gap and the exponential decay of the eigenfunctions, we prove a limit theorem for the random walk under the Gibbs measure associated to the potential .
Paper Structure (14 sections, 22 theorems, 155 equations)

This paper contains 14 sections, 22 theorems, 155 equations.

Table of Contents

  1. Introduction
  2. General notations
  3. Spectra of the operator $P_V$
  4. Limit of the random walk in potential $V$
  5. An example in dimension one
  6. Proof of Theorem \ref{['Thm.ess']} and Corollary \ref{['Cor.ess']}
  7. Outline
  8. Lemmas
  9. Proof of Theorem \ref{['Thm.decay']}
  10. Outline
  11. Lemmas
  12. Proof of Theorem \ref{['Thm.gap']}, Corollary \ref{['Cor.gap']} and Proposition \ref{['Prop.cond*gap']}
  13. Outline
  14. Lemmas

Key Result

Theorem 1.2.1

Suppose that $V:{\mathbb{Z}}^d \rightarrow [0,\infty)$ is a bounded function such that Then, where

Theorems & Definitions (22)

  • Theorem 1.2.1
  • Corollary 1.2.2
  • Theorem 1.2.3
  • Theorem 1.2.4
  • Corollary 1.2.5
  • Proposition 1.2.6
  • Theorem 1.3.1
  • Lemma 2.2.1
  • Lemma 2.2.2
  • Lemma 2.2.3
  • ...and 12 more