Litcius/Paper detail

Lévy-Rosenzweig-Porter random matrix ensemble

Giulio Biroli, Marco Tarzia

2021Physical review. B./Physical review. B69 citationsDOIOpen Access PDF

Abstract

In this paper, we consider an extension of the Rosenzweig-Porter model, the L\'evy-RP (L-RP) model, in which the off-diagonal matrix elements are broadly distributed, providing a more realistic benchmark to develop an effective description of nonergodic extended (NEE) states in interacting many-body disordered systems. We put forward a simple, general, and intuitive argument that allows one to unveil the multifractal structure of the minibands in the local spectrum when hybridization is due to anomalously large transition amplitudes in the tails of the distribution. The idea is that the energy spreading of the minibands can be determined self-consistently by requiring that the maximal hybridization rate ${\mathcal{H}}_{ij}$ between a site $i$ and the other ${N}^{{D}_{1}}$ sites of the support set is of the same order of the Thouless energy itself ${N}^{{D}_{1}\ensuremath{-}1}$. This argument yields the fractal dimensions that characterize the statistics of the multifractal wave functions in the NEE phase, as well as the whole phase diagram of the L-RP ensemble. Its predictions are confirmed both analytically, by a thorough investigation of the self-consistent equation for the local density of states obtained using the cavity approach, and numerically, via extensive exact diagonalizations.

Topics & Concepts

Multifractal systemStatistical physicsErgodic theoryRandom matrixDiagonalFractalMatrix (chemical analysis)PhysicsMathematicsMathematical physicsQuantum mechanicsMathematical analysisMaterials scienceEigenvalues and eigenvectorsComposite materialGeometryQuantum many-body systemsOpinion Dynamics and Social InfluenceTheoretical and Computational Physics
Lévy-Rosenzweig-Porter random matrix ensemble | Litcius