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Quantum Relative Entropy and the Mean-Field Limit

2 Pith papers cite this work. Polarity classification is still indexing.

2 Pith papers citing it
abstract

We develop a quantum relative entropy method for the mean-field limit of quantum many-body systems. For closed systems governed by the von Neumann equation, we prove a quantitative stability estimate between the $N$-body density matrix and the tensorized solution of the Hartree equation. The argument is based on an entropy production identity, a cancellation mechanism for the centered two-body fluctuation, and a combinatorial estimate controlling the remaining mixed moments. As a consequence, we obtain propagation of chaos in trace norm for fixed marginals. We further combine the entropy estimate with known semiclassical Wasserstein bounds to derive a convergence estimate that is uniform in the Planck constant in an appropriate joint mean-field and semiclassical regime. Finally, we extend the method to finite-dimensional open quantum systems governed by Lindblad dynamics. In this setting, we establish an analogous relative entropy estimate for general bounded two-body interactions, where the mean-field potential is defined through partial trace. This shows that the entropy method does not rely on any special tensor-product decomposition of the interaction.

years

2026 2

verdicts

UNVERDICTED 2

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Showing 2 of 2 citing papers.

  • Purified Projection Method and Uhlmann Fidelity for Mixed Hartree Dynamics math-ph · 2026-05-27 · unverdicted · none · ref 13 · internal anchor

    Authors prove quantitative propagation of chaos for mixed Hartree evolutions in squared Uhlmann fidelity then trace norm, using purified projection and rank-one counting estimates, for interactions satisfying a projected-square bound.

  • Propagation of chaos for Belavkin equations beyond pure states math.PR · 2026-06-28 · unverdicted · none · ref 10 · 2 links · internal anchor

    Proves quantitative trace-norm propagation of chaos for Belavkin equations on mixed-state density matrices in finite-dimensional quantum mean-field systems.