The 1st law of thermodynamics for the mean energy of a closed quantum system in the Aharonov-Vaidman gauge (Q2352953)

Summary: The Aharonov-Vaidman gauge additively transforms the mean energy of a quantum mechanical system into a weak valued system energy. In this paper, the equation of motion of this weak valued energy is used to provide a mathematical statement of an extended 1st Law of Thermodynamics that is applicable to the mean energy of a closed quantum system when the mean energy is expressed in the Aharonov-Vaidman gauge, i.e., when the system's energy is weak valued. This is achieved by identifying the generalized heat and work exchange terms that appear in the equation of motion for weak valued energy. The complex valued contributions of the additive gauge term to these generalized exchange terms are discussed and this extended 1st Law is shown to subsume the usual 1st Law that is applicable for the mean energy of a closed quantum system. It is found that the gauge transformation introduces an additional energy uncertainty exchange term that -- while it is neither a heat nor a work exchange term -- is necessary for the conservation of weak valued energy. A spin-\(1/2\) particle in a uniform magnetic field is used to illustrate aspects of the theory. It is demonstrated for this case that the extended 1st Law implies the existence of a gauge potential \(\omega\) and that it generates a non-vanishing gauge field \(F\). It is also shown for this case that the energy uncertainty exchange accumulated during the evolution of the system along a closed evolutionary cycle \(C\) in an associated parameter space is a geometric phase. This phase is equal to both the path integral of \(\omega\) along \(C\) and the integral of the flux of \(F\) through the area enclosed by \(C\).