Dynamics of colored-noise-driven stochastic Schrödinger equations (2507.17864v1)

Abstract: In this work, we study the effect of colored stochastic noise as a source of fluctuations in the dynamics of a two-level system, e.g. the states of a qubit system or two local sites in a transfer problem. We derive the stochastic Schr\"odinger equations (SSE) and related quantum master equations (QME) for the average density matrix for different stochastic potentials. We compare the case of memory and memoryless processes, which reflect different short-time behaviors and, in some cases, can lead to different stationary distributions of the average system state. Focusing on the use of an Ornstein-Uhlenbeck coloured noise driving the dynamics, in the same fashion as the white noise is the formal derivative of a Wiener process, we shed light on how different dissipative terms of a generic QME arise depending on the nature of the stochastic potential involved, and their effect on the short and long time evolution of the system. We rationalize the emergence of the different terms in terms of the time- and frequency-dependent coefficients Redfield QME. Within this framework, we explicitly derive a closure model for the open terms in the QME derived from the SSE approach, and clarify how colored noise impacts the coherence relaxation time scales