Quantum Energy Current Induced Coherence in a Spin Chain under Non-Markovian Environments

Abstract: We investigate the time-dependent behaviour of the energy current between a quantum spin chain and its surrounding non-Markovian and finite temperature baths, together with its relationship to the coherence dynamics of the system. To be specific, both the system and the baths are assumed to be initially in thermal equilibrium at temperature Ts and Tb, respectively. This model plays a fundamental role in study of quantum system evolution towards thermal equilibrium in an open system. The non-Markovian quantum s… Show more

“…However, different quantum coherence monotones for interacting spin systems, particularly represented by Heisenberg models, have been throughly investigated under thermal equilibrium, analyzing the effects of temperature, external magnetic field, interaction strength, and anisotropy on the quantum coherence. For these studies, we refer the readers to the references [42][43][44][45][46].…”

Quantum coherence resourced by the strong nuclear quadrupolar interaction

“…However, different quantum coherence monotones for interacting spin systems, particularly represented by Heisenberg models, have been throughly investigated under thermal equilibrium, analyzing the effects of temperature, external magnetic field, interaction strength, and anisotropy on the quantum coherence. For these studies, we refer the readers to the references [42][43][44][45][46].…”

Quantum coherence resourced by the strong nuclear quadrupolar interaction

Enhanced adiabatic quantum algorithm in finite-temperature reservoirs via squeezing

Optimized control for high-fidelity state transmission in open systems