Multi-Particle Anderson Localisation: Induction on the Number of Particles

Abstract

This paper is a follow-up of our recent papers CS08 and CS09 covering the two-particle Anderson model. Here we establish the phenomenon of Anderson localisation for a quantum N-particle system on a lattice d with short-range interaction and in presence of an IID external potential with sufficiently regular marginal cumulative distribution function (CDF). Our main method is an adaptation of the multi-scale analysis (MSA; cf. FS, FMSS, DK) to multi-particle systems, in combination with an induction on the number of particles, as was proposed in our earlier manuscript CS07. Similar results have been recently obtained in an independent work by Aizenman and Warzel AW08: they proposed an extension of the Fractional-Moment Method (FMM) developed earlier for single-particle models in AM93 and ASFH01 (see also references therein) which is also combined with an induction on the number of particles. An important role in our proof is played by a variant of Stollmann's eigenvalue concentration bound (cf. St00). This result, as was proved earlier in C08, admits a straightforward extension covering the case of multi-particle systems with correlated external random potentials: a subject of our future work. We also stress that the scheme of our proof is not specific to lattice systems, since our main method, the MSA, admits a continuous version. A proof of multi-particle Anderson localization in continuous interacting systems with various types of external random potentials will be published in a separate papers.