Thouless numbers for few-particle systems with disorder and interactions

Abstract

Considering N spinless Fermions in a random potential, we study how a short range pairwise interaction delocalizes the N-body states in the basis of the one-particle Slater determinants, and the spectral rigidity of the N-body spectrum. The maximum number gN of consecutive levels exhibiting the universal Wigner-Dyson rigidity (the Thouless number) is given as a function of the strength U of the interaction for the bulk of the spectrum. In the dilute limit, one finds two thresholds: When U<Uc1, there is a perturbative mixing between a few Slater determinants (Rabi oscillations) and gN |U|P <1, where P=N/2 (even N) or (N+1)/2 (odd N). When U=Uc1, the level spacing distribution exhibits a crossover from Poisson to Wigner, related to the crossover between weak perturbative mixing and effective golden-rule decay, and gN ≈ 1. Moreover, we show that the same Uc1 signifies also the breakdown of the perturbation theory in U. For Uc1<U<Uc2, the states are extended over the energetically nearby Slater determinants with a non-ergodic hierarchical structure related to the sparse form of the Hamiltonian. Above a second threshold Uc2, the sparsity becomes irrelevant, and the states are extended more or less ergodically over gN consecutive Slater determinants. A self-consistent argument gives gN ~ UN/(N-1). We compare our predictions to a numerical study of three spinless Fermions in a disordered cubic lattice. Implications for the interaction-induced N-particle delocalization in real space are discussed. The applicability of Fermi's golden rule for decay in this dilute gas of "real" particles is compared with the one characterizing a finite-density Fermi gas. The latter is related to the recently suggested Anderson transition in Fock space.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…