Massimiliano Esposito, Shaul Mukamel
Published 2006-02-28Version 1
A quantum fluctuation theorem for a driven quantum subsystem interacting with its environment is derived based solely on the assumption that its reduced density matrix obeys a closed evolution equation i.e. a quantum master equation (QME). Quantum trajectories and their associated entropy, heat and work appear naturally by transforming the QME to a time dependent Liouville space basis that diagonalizes the instantaneous reduced density matrix of the subsystem. A quantum integral fluctuation theorem, a steady state fluctuation theorem and the Jarzynski relation are derived in a similar way as for classical stochastic dynamics.
Comments: Submitted to Phys. Rev. E
Journal: Phys. Rev. E 73, 046129 (2006)
From quantum master equation to random walk
Unified Treatment of Quantum Fluctuation Theorem and Jarzynski Equality in Terms of microscopic reversibility
Quantum fluctuation theorem for heat exchange in the strong coupling regime
