Magnetic aftereffect experiments at low temperature: Linear response and quantum noise

J. E. Wegrowe; R. Ballou; B. Barbara; A. Sulpice; V. S. Amaral; D. Mailly

doi:10.1103/PhysRevB.52.3466

Magnetic aftereffect experiments at low temperature: Linear response and quantum noise

J. E. Wegrowe
, R. Ballou
, B. Barbara
, A. Sulpice
, V. S. Amaral
, D. Mailly

Centre national de la recherche scientifique
Ipatimup Diagnósticos

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

Abstract

An alternative approach to slow magnetic relaxation at low temperature is proposed in terms of a linear response theory involving collective variables characteristic of local metastable states. The model leads to the definition of two types of magnetic viscosity: S0 due to the response to an excitation field and S1 due to the response to an initial thermal perturbation. The thermal behavior of the magnetic viscosity is found to be S0K(T)/kBT in the first case, and S1K(T) in the second case, where K(T) is the thermal noise. Experimental results, interpreted as the manifestation of the magnetic viscosity S0, show some evidence of a noise K(T), which can be interpreted as a quantum form of the noise.

Original language	English
Pages (from-to)	3466-3470
Number of pages	5
Journal	Physical Review B
Volume	52
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevB.52.3466
Publication status	Published - 1 Jan 1995

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title = "Magnetic aftereffect experiments at low temperature: Linear response and quantum noise",

abstract = "An alternative approach to slow magnetic relaxation at low temperature is proposed in terms of a linear response theory involving collective variables characteristic of local metastable states. The model leads to the definition of two types of magnetic viscosity: S0 due to the response to an excitation field and S1 due to the response to an initial thermal perturbation. The thermal behavior of the magnetic viscosity is found to be S0K(T)/kBT in the first case, and S1K(T) in the second case, where K(T) is the thermal noise. Experimental results, interpreted as the manifestation of the magnetic viscosity S0, show some evidence of a noise K(T), which can be interpreted as a quantum form of the noise.",

author = "Wegrowe, \{J. E.\} and R. Ballou and B. Barbara and A. Sulpice and Amaral, \{V. S.\} and D. Mailly",

year = "1995",

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T2 - Linear response and quantum noise

AU - Wegrowe, J. E.

AU - Ballou, R.

AU - Barbara, B.

AU - Sulpice, A.

AU - Amaral, V. S.

AU - Mailly, D.

PY - 1995/1/1

Y1 - 1995/1/1

N2 - An alternative approach to slow magnetic relaxation at low temperature is proposed in terms of a linear response theory involving collective variables characteristic of local metastable states. The model leads to the definition of two types of magnetic viscosity: S0 due to the response to an excitation field and S1 due to the response to an initial thermal perturbation. The thermal behavior of the magnetic viscosity is found to be S0K(T)/kBT in the first case, and S1K(T) in the second case, where K(T) is the thermal noise. Experimental results, interpreted as the manifestation of the magnetic viscosity S0, show some evidence of a noise K(T), which can be interpreted as a quantum form of the noise.

AB - An alternative approach to slow magnetic relaxation at low temperature is proposed in terms of a linear response theory involving collective variables characteristic of local metastable states. The model leads to the definition of two types of magnetic viscosity: S0 due to the response to an excitation field and S1 due to the response to an initial thermal perturbation. The thermal behavior of the magnetic viscosity is found to be S0K(T)/kBT in the first case, and S1K(T) in the second case, where K(T) is the thermal noise. Experimental results, interpreted as the manifestation of the magnetic viscosity S0, show some evidence of a noise K(T), which can be interpreted as a quantum form of the noise.

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DO - 10.1103/PhysRevB.52.3466

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VL - 52

SP - 3466

EP - 3470

JO - Physical Review B

JF - Physical Review B

IS - 5

ER -

Magnetic aftereffect experiments at low temperature: Linear response and quantum noise

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