Entropy-based formulation of thermodynamics in arbitrary quantum evolution
Given the evolution of an arbitrary open quantum system, we formulate a general and unambiguous method to separate the internal energy change of the system into an entropy-related contribution and a part causing no entropy change, identified as heat and work, respectively. We also demonstrate that heat and work admit geometric and dynamical descriptions by developing a universal dynamical equation for the given trajectory of the system. The dissipative and coherent parts of this equation contribute exclusively to heat and work, where the specific role of a work contribution from a counterdiabatic drive is underlined. Next we define an expression for the irreversible entropy production of the system which does not have explicit dependence on the properties of the ambient environment; rather, it depends on a set of the system's observables excluding its Hamiltonian and is independent of internal energy change. We illustrate our results with three examples.
Funding
Academy of Finland’s Center of Excellence QTF Project 31229
Sharif University of Technology’s Office of Vice President for Research
History
School
- Science
Department
- Mathematical Sciences
Published in
Physical Review AVolume
105Issue
4Publisher
American Physical Society (APS)Version
- AM (Accepted Manuscript)
Rights holder
© American Physical SocietyPublisher statement
This paper was accepted for publication in the journal Physical Review A and the definitive published version is available at https://doi.org/10.1103/physreva.105.l040201Acceptance date
2022-03-09Publication date
2022-04-18Copyright date
2022ISSN
2469-9926eISSN
2469-9934Publisher version
Language
- en