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The effective potential of an <i>M</i>-matrix

Marcel Filoche, Svitlana Mayboroda, Terence Tao

2021Journal of Mathematical Physics19 citationsDOIOpen Access PDF

Abstract

In the presence of a confining potential V, the eigenfunctions of a continuous Schrödinger operator −Δ + V decay exponentially with the rate governed by the part of V, which is above the corresponding eigenvalue; this can be quantified by a method of Agmon. Analogous localization properties can also be established for the eigenvectors of a discrete Schrödinger matrix. This note shows, perhaps surprisingly, that one can replace a discrete Schrödinger matrix by any real symmetric Z-matrix and still obtain eigenvector localization estimates. In the case of a real symmetric non-singular M-matrix A (which is a situation that arises in several contexts, including random matrix theory and statistical physics), the landscape function u = A−11 plays the role of an effective potential of localization. Starting from this potential, one can create an Agmon-type distance function governing the exponential decay of the eigenfunctions away from the “wells” of the potential, a typical eigenfunction being localized to a single such well.

Topics & Concepts

EigenfunctionEigenvalues and eigenvectorsMatrix (chemical analysis)Random matrixOperator (biology)Function (biology)MathematicsMathematical physicsMathematical analysisExponential functionPhysicsQuantum mechanicsChemistryRepressorBiologyBiochemistryMaterials scienceGeneEvolutionary biologyComposite materialTranscription factorQuantum many-body systemsRandom Matrices and ApplicationsQuantum Information and Cryptography