pith. sign in

Microscopic diagonal entropy and its connection to basic thermodynamic relations

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

2 Pith papers citing it
abstract

We define a diagonal entropy (d-entropy) for an arbitrary Hamiltonian system as $S_d=-\sum_n \rho_{nn}\ln \rho_{nn}$ with the sum taken over the basis of instantaneous energy states. In equilibrium this entropy coincides with the conventional von Neumann entropy $S_n=-{\rm Tr}\, \rho\ln\rho$. However, in contrast to $S_n$, the d-entropy is not conserved in time in closed Hamiltonian systems. If the system is initially in stationary state then in accord with the second law of thermodynamics the d-entropy can only increase or stay the same. We also show that the d-entropy can be expressed through the energy distribution function and thus it is measurable, at least in principle. Under very generic assumptions of the locality of the Hamiltonian and non-integrability the d-entropy becomes a unique function of the average energy in large systems and automatically satisfies the fundamental thermodynamic relation. This relation reduces to the first law of thermodynamics for quasi-static processes. The d-entropy is also automatically conserved for adiabatic processes. We illustrate our results with explicit examples and show that $S_d$ behaves consistently with expectations from thermodynamics.

fields

quant-ph 2

years

2026 2

verdicts

UNVERDICTED 2

representative citing papers

Emergence of Thermodynamics from Equilibration in Isolated Quantum Systems

quant-ph · 2026-06-27 · unverdicted · novelty 6.0

Any continuously differentiable function of equilibrating expectation values equilibrates, implying subsystem entropy and conjugate variables equilibrate and total entropy is dynamically maximized under local conservation in bipartite isolated quantum systems.

citing papers explorer

Showing 2 of 2 citing papers.