Quantum Fokker-Planck Dynamics
Abstract
The Fokker-Planck equation is a partial differential equation which is a key ingredient in many models in physics. This paper aims to obtain a quantum counterpart of Fokker-Planck dynamics, as a means to describing quantum Fokker-Planck dynamics. Given that relevant models relate to the description of large systems, the quantization of the Fokker-Planck equation should be done in a manner that respects this fact, and is therefore carried out within the setting of non-commutative analysis based on general von Neumann algebras. Within this framework we present a quantization of the generalized Laplace operator, and then go on to incorporate a potential term conditioned to noncommutative analysis. In closing we then construct and examine the asymptotic behaviour of the corresponding Markov semigroups. We also present a noncommutative Csiszar-Kullback inequality formulated in terms of a notion of relative entropy, and show that for more general systems, good behaviour with respect to this notion of entropy ensures similar asymptotic behaviour of the relevant dynamics.
Cite
@article{arxiv.2106.05718,
title = {Quantum Fokker-Planck Dynamics},
author = {Louis Labuschagne and W. Adam Majewski},
journal= {arXiv preprint arXiv:2106.05718},
year = {2022}
}
Comments
The final version submitted to AHP. A brief account of applied quantization as well as the comprehensive description of closability of quantum Laplacian is added