Related papers: Macroscopic Irreversibility in Quantum Systems: ETH and Equilibration in a Free Fermion Chain

Macroscopic Irreversibility in Quantum Systems: ETH and Equilibration in a Free Fermion Chain

URL: http://arxiv.org/abs/2401.15263v3
Date: Fri, 10 May 2024 02:41:12 GMT
Title: Macroscopic Irreversibility in Quantum Systems: ETH and Equilibration in a Free Fermion Chain
Authors: Hal Tasaki,
Abstract summary: We consider a free fermion chain with uniform nearest-neighbor hopping and let it evolve from an arbitrary initial state with a fixed macroscopic number of particles. We prove that, at a sufficiently large and typical time, the measured coarse-grained density distribution is almost uniform with (quantum mechanical) probability extremely close to one. This establishes the emergence of irreversible behavior, i.e., a ballistic diffusion, in a system governed by quantum mechanical unitary time evolution.
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License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We consider a free fermion chain with uniform nearest-neighbor hopping and let it evolve from an arbitrary initial state with a fixed macroscopic number of particles. We then prove that, at a sufficiently large and typical time, the measured coarse-grained density distribution is almost uniform with (quantum mechanical) probability extremely close to one. This establishes the emergence of irreversible behavior, i.e., a ballistic diffusion, in a system governed by quantum mechanical unitary time evolution. It is conceptually important that irreversibility is proved here without introducing any randomness to the initial state or the Hamiltonian, while the derivation of irreversibility in classical systems mostly relies on certain randomness. The essential new ingredient in the proof is the justification of the strong ETH (energy eigenstate thermalization hypothesis) in the large-deviation form.

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