Related papers: Quantum master equation from the eigenstate thermalization hypothesis

Quantum master equation from the eigenstate thermalization hypothesis

URL: http://arxiv.org/abs/2411.07706v1
Date: Tue, 12 Nov 2024 10:44:00 GMT
Title: Quantum master equation from the eigenstate thermalization hypothesis
Authors: Peter O'Donovan, Philipp Strasberg, Kavan Modi, John Goold, Mark T. Mitchison,
Abstract summary: We show that the emergence of Markovianity is controlled by the spectral function of the ETH. We numerically verify this result by comparing the master equation to dynamics computed using exact diagonalization of a chaotic Hamiltonian.
Score: 0.20971479389679332
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Abstract: We use the eigenstate thermalization hypothesis to derive a quantum master equation for a system weakly coupled to a chaotic finite-sized bath prepared in a pure state. We show that the emergence of Markovianity is controlled by the spectral function of the ETH and that local detailed balance emerges in the Markovian regime for a broad class of pure bath states. We numerically verify this result by comparing the master equation to dynamics computed using exact diagonalization of a chaotic Hamiltonian. We also compare the master equation to exact dynamics for an integrable bath and find that at finite size they strongly disagree. Our work puts forward eigenstate thermalization as a foundation for open quantum systems theory, thus extending it beyond ensemble bath preparations to chaotic many-body environments in generic pure states.

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