Typical Macroscopic Long-Time Behavior for Random Hamiltonians
Abstract
We consider a closed macroscopic quantum system in a pure state evolving unitarily and take for granted that different macro states correspond to mutually orthogonal subspaces (macro spaces) of Hilbert space, each of which has large dimension. We extend previous work on the question what the evolution of looks like macroscopically, specifically on how much of lies in each . Previous bounds concerned the \emph{absolute} error for typical and/or and are valid for arbitrary Hamiltonians ; now, we provide bounds on the \emph{relative} error, which means much tighter bounds, with probability close to 1 by modeling as a random matrix, more precisely as a random band matrix (i.e., where only entries near the main diagonal are significantly nonzero) in a basis aligned with the macro spaces. We exploit particularly that the eigenvectors of are delocalized in this basis. Our main mathematical results confirm the two phenomena of generalized normal typicality (a type of long-time behavior) and dynamical typicality (a type of similarity within the ensemble of from an initial macro space). They are based on an extension we prove of a no-gaps delocalization result for random matrices by Rudelson and Vershynin.
Cite
@article{arxiv.2303.13242,
title = {Typical Macroscopic Long-Time Behavior for Random Hamiltonians},
author = {Stefan Teufel and Roderich Tumulka and Cornelia Vogel},
journal= {arXiv preprint arXiv:2303.13242},
year = {2025}
}
Comments
46 pages LaTeX, 2 figure files; v2 has tighter error bounds in Sec. 7 and minor improvements throughout the paper