Quantum mechanical transitions in a dissipative environment

Seiji Miyashita; Keiji Saito; Hans De Raedt

doi:10.1143/PTPS.138.501

Quantum mechanical transitions in a dissipative environment

Seiji Miyashita, Keiji Saito, Hans De Raedt

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

We have constructed an algorithm to treat quantum mechanical dynamics, such as the nonadiabatic transitions in a dissipative environment, by making use of the formula of reduced density matrix, i.e., Quantum Master Equation (QME). We applied the method to investigate dynamics of magnetization of nanoscale magnets, such as Mn₁₂ and Fe₈, in a time dependent field. Due to the discreteness of the energy levels in small systems the resonating tunneling phenomena play an important role. At relatively high temperatures the excited levels contribute to the transition and the transition rate depends significantly on the temperature. On the other hand, at very low temperatures the magnetization process does not depend on the temperature. Even at such a low temperature, the effect of environments is still relevant. We demonstrate such a process with the method of QME. We also analyze temperature dependent phenomena of hysteresis of the nanoscale magnets.

Original language	English
Pages (from-to)	501-506
Number of pages	6
Journal	Progress of Theoretical Physics Supplement
Issue number	138
DOIs	https://doi.org/10.1143/PTPS.138.501
Publication status	Published - 2000
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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abstract = "We have constructed an algorithm to treat quantum mechanical dynamics, such as the nonadiabatic transitions in a dissipative environment, by making use of the formula of reduced density matrix, i.e., Quantum Master Equation (QME). We applied the method to investigate dynamics of magnetization of nanoscale magnets, such as Mn12 and Fe8, in a time dependent field. Due to the discreteness of the energy levels in small systems the resonating tunneling phenomena play an important role. At relatively high temperatures the excited levels contribute to the transition and the transition rate depends significantly on the temperature. On the other hand, at very low temperatures the magnetization process does not depend on the temperature. Even at such a low temperature, the effect of environments is still relevant. We demonstrate such a process with the method of QME. We also analyze temperature dependent phenomena of hysteresis of the nanoscale magnets.",

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AU - Miyashita, Seiji

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Quantum mechanical transitions in a dissipative environment

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