Quantum dynamics in nanoscale magnets in dissipative environments

S Miyashita; K Saito; H. Kobayashi; H.A. de Raedt

Quantum dynamics in nanoscale magnets in dissipative environments

S Miyashita^*, K Saito, H. Kobayashi, H.A. de Raedt

^*Corresponding author for this work

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Abstract

In discrete energy structure of nanoscale magnets, nonadiabatic transitions at avoided level crossings lead to fundamental processes of dynamics of magnetizations. The thermal environment causes dissipative effects on these processes. In this paper we review the features of the nonadiabatic transition and the influence of the thermal environment. In particular we discuss the temperature independent stepwise structure of magnetization at very low temperatures (deceptive nonadiabatic transition), the alternate enhancement of relaxation in the sequence of resonant tunneling points (parity effects), and processes caused by combinations of nonadiabatic transitions and disturbance due to external noises.

Original language	English
Pages (from-to)	395 - 400
Number of pages	6
Journal	Journal of the Physical Society of Japan
Volume	69
Issue number	1
Publication status	Published - 2000

Keywords

nanoscale magnets
nonadiabatic transitions
Landau-Zener-Stuckelberg transitions
dissipative environments
SINGLE-CRYSTAL
MAGNETIZATION
FIELD
PROTEINS
CLUSTERS
FERRITIN
SYSTEM
MODEL

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@article{8c6a67f9178e4a0db1f35d3d91fb29a8,

title = "Quantum dynamics in nanoscale magnets in dissipative environments",

abstract = "In discrete energy structure of nanoscale magnets, nonadiabatic transitions at avoided level crossings lead to fundamental processes of dynamics of magnetizations. The thermal environment causes dissipative effects on these processes. In this paper we review the features of the nonadiabatic transition and the influence of the thermal environment. In particular we discuss the temperature independent stepwise structure of magnetization at very low temperatures (deceptive nonadiabatic transition), the alternate enhancement of relaxation in the sequence of resonant tunneling points (parity effects), and processes caused by combinations of nonadiabatic transitions and disturbance due to external noises.",

keywords = "nanoscale magnets, nonadiabatic transitions, Landau-Zener-Stuckelberg transitions, dissipative environments, SINGLE-CRYSTAL, MAGNETIZATION, FIELD, PROTEINS, CLUSTERS, FERRITIN, SYSTEM, MODEL",

author = "S Miyashita and K Saito and H. Kobayashi and {de Raedt}, H.A.",

note = "Relation: http://www.rug.nl/zernike/ date_submitted:2007 Rights: University of Groningen. Zernike Institute for Advanced Materials",

year = "2000",

language = "English",

volume = "69",

pages = "395 -- 400",

journal = "Journal of the Physical Society of Japan",

publisher = "PHYSICAL SOC JAPAN",

number = "1",

}

TY - JOUR

T1 - Quantum dynamics in nanoscale magnets in dissipative environments

AU - Miyashita, S

AU - Saito, K

AU - Kobayashi, H.

AU - de Raedt, H.A.

N1 - Relation: http://www.rug.nl/zernike/ date_submitted:2007 Rights: University of Groningen. Zernike Institute for Advanced Materials

PY - 2000

Y1 - 2000

N2 - In discrete energy structure of nanoscale magnets, nonadiabatic transitions at avoided level crossings lead to fundamental processes of dynamics of magnetizations. The thermal environment causes dissipative effects on these processes. In this paper we review the features of the nonadiabatic transition and the influence of the thermal environment. In particular we discuss the temperature independent stepwise structure of magnetization at very low temperatures (deceptive nonadiabatic transition), the alternate enhancement of relaxation in the sequence of resonant tunneling points (parity effects), and processes caused by combinations of nonadiabatic transitions and disturbance due to external noises.

AB - In discrete energy structure of nanoscale magnets, nonadiabatic transitions at avoided level crossings lead to fundamental processes of dynamics of magnetizations. The thermal environment causes dissipative effects on these processes. In this paper we review the features of the nonadiabatic transition and the influence of the thermal environment. In particular we discuss the temperature independent stepwise structure of magnetization at very low temperatures (deceptive nonadiabatic transition), the alternate enhancement of relaxation in the sequence of resonant tunneling points (parity effects), and processes caused by combinations of nonadiabatic transitions and disturbance due to external noises.

KW - nanoscale magnets

KW - nonadiabatic transitions

KW - Landau-Zener-Stuckelberg transitions

KW - dissipative environments

KW - SINGLE-CRYSTAL

KW - MAGNETIZATION

KW - FIELD

KW - PROTEINS

KW - CLUSTERS

KW - FERRITIN

KW - SYSTEM

KW - MODEL

M3 - Article

VL - 69

SP - 395

EP - 400

JO - Journal of the Physical Society of Japan

JF - Journal of the Physical Society of Japan

IS - 1

ER -

Quantum dynamics in nanoscale magnets in dissipative environments

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Keywords

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