Abstract
We present an alternative formulation of quantum decoherence theory using conditional wave theory (CWT), which was originally developed in molecular physics (also known as exact factorisation methods). We formulate a CWT of a classic model of collisional decoherence of a free particle with environmental particles treated in a long-wavelength limit. In general, the CWT equation of motion for the particle is non-linear, where the non-linearity enters via the CWT gauge fields. For Gaussian wave packets the analytic solutions of the CWT equations are in exact agreement with those from the density matrix formalism. We show that CWT gauge terms that determine the dynamics of the particle's marginal wave function are related to a Taylor series expansion of the particle's reduced density matrix. Approximate solutions to these equations lead to a linear-time approximation that reproduces the ensemble width in the limits of both short and long times, in addition to reproducing the long-term behaviour of the coherence length. With this approximation, the non-linear equation of motion for the particle's marginal wave function can be written in the form of the logarithmic Schr\"odinger equation. The CWT formalism may lead to computationally efficient calculations of quantum decoherence, since it involves working with wave-function level terms instead of evolving a density matrix via a master equation.
Highlights
The interactions of quantum systems with their environments is of critical importance for the development of quantum technologies and for our understanding of the quantum world [1,2]
We show that the conditional wave theory (CWT) gauge terms are related to the firstorder terms in a Taylor series expansion of the density matrix
It is of fundamental interest that the logarithmic Schrödinger equation appears in the CWT of quantum decoherence and may lead new understanding about the dynamics induced by decoherence processes
Summary
The interactions of quantum systems with their environments is of critical importance for the development of quantum technologies and for our understanding of the quantum world [1,2]. The state of an open quantum system is modeled by a reduced density matrix ρ(r, r , t ) and its equation of motion is known as a master equation. We present an alternative approach to modeling quantum decoherence based on the technique of exact factorization [8,9], which has been developed in the context of molecular physics. The higher order terms in the expansion are related to higher order spatial derivatives of the environment’s conditional state This has important consequences for the time evolution of the CWT gauge terms, which are part of infinite series of coupled equations. Without approximation, the CWT formalism treatment of decoherence involves the same number of equations as the density matrix formalism. It is of fundamental interest that the logarithmic Schrödinger equation appears in the CWT of quantum decoherence and may lead new understanding about the dynamics induced by decoherence processes
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