Modelling magnetostructural textures in magnetic shape-memory alloys: Strain and magnetic glass behaviour

Modelling magnetostructural textures in magnetic shape-memory alloys: Strain and magnetic glass behaviour

In this paper, we propose a model that combines a Landau free energy part and a micromagnetic free energy part aimed at describing a magnetostructural multiferroic. We show that in the limit of high‐elastic anisotropy and strong magnetostructural interplay, the model is able to reproduce characteris...

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Published in:Physica Status Solidi. B: Basic Solid State Physics Vol. 251; no. 10; pp. 2080 - 2087
Main Authors: Lloveras, Pol, Touchagues, Gilles, Castán, Teresa, Lookman, Turab, Porta, Marcel, Saxena, Avadh, Planes, Antoni
Format: Journal Article Publication
Language:English
Published: Blackwell Publishing Ltd 01-10-2014
Subjects:
Anisotropy
Energies
Enginyeria dels materials
Free energy
Glass
Magnetic glass
Magnetic materials
Magnetic shape memory
Magnetism
Magnetisme
Magnetization
Martensitic transition
Materials funcionals
Materials magnètics
Mathematical models
Shape memory
Strain
Strain glass
Texture
Àrees temàtiques de la UPC
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Abstract In this paper, we propose a model that combines a Landau free energy part and a micromagnetic free energy part aimed at describing a magnetostructural multiferroic. We show that in the limit of high‐elastic anisotropy and strong magnetostructural interplay, the model is able to reproduce characteristic strain and magnetization configurations typical of magnetic shape‐memory materials. For low‐elastic anisotropy, in the presence of disorder arising from compositional fluctuations giving rise to a distribution of local transition temperatures, the model is able to reproduce strain glass behaviour. In this case, the temperature dependence of the magnetization measured after zero magnetic field cooling deviates from the magnetization measured after magnetic field cooling protocol, which proves that the strain glass behaviour induces non‐ergodicity in the magnetic degrees of freedom as well. Lloveras et al. study a model for systems undergoing a magnetostructural transition that combines a Ginzburg–Landau free energy accounting for the structural contribution together with a micromagnetic term that describes the magnetic and magnetostructural contributions. Both strain and magnetic glass behaviour is predicted to occur in off‐stoichiometric magnetic shape‐memory materials with low elastic anisotropy.
AbstractList In this paper, we propose a model that combines a Landau free energy part and a micromagnetic free energy part aimed at describing a magnetostructural multiferroic. We show that in the limit of high‐elastic anisotropy and strong magnetostructural interplay, the model is able to reproduce characteristic strain and magnetization configurations typical of magnetic shape‐memory materials. For low‐elastic anisotropy, in the presence of disorder arising from compositional fluctuations giving rise to a distribution of local transition temperatures, the model is able to reproduce strain glass behaviour. In this case, the temperature dependence of the magnetization measured after zero magnetic field cooling deviates from the magnetization measured after magnetic field cooling protocol, which proves that the strain glass behaviour induces non‐ergodicity in the magnetic degrees of freedom as well. Lloveras et al. study a model for systems undergoing a magnetostructural transition that combines a Ginzburg–Landau free energy accounting for the structural contribution together with a micromagnetic term that describes the magnetic and magnetostructural contributions. Both strain and magnetic glass behaviour is predicted to occur in off‐stoichiometric magnetic shape‐memory materials with low elastic anisotropy.
In this paper, we propose a model that combines a Landau free energy part and a micromagnetic free energy part aimed at describing a magnetostructural multiferroic. We show that in the limit of high-elastic anisotropy and strong magnetostructural interplay, the model is able to reproduce characteristic strain and magnetization configurations typical of magnetic shapememory materials. For low-elastic anisotropy, in the presence of disorder arising from compositional fluctuations giving rise to a distribution of local transition temperatures, the model is able to reproduce strain glass behaviour. In this case, the temperature dependence of the magnetization measured after zero magnetic field cooling deviates from the magnetization measured after magnetic field cooling protocol, which proves that the strain glass behaviour induces non-ergodicity in the magnetic degrees of freedom as well. (C) 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
In this paper, we propose a model that combines a Landau free energy part and a micromagnetic free energy part aimed at describing a magnetostructural multiferroic. We show that in the limit of high-elastic anisotropy and strong magnetostructural interplay, the model is able to reproduce characteristic strain and magnetization configurations typical of magnetic shape-memory materials. For low-elastic anisotropy, in the presence of disorder arising from compositional fluctuations giving rise to a distribution of local transition temperatures, the model is able to reproduce strain glass behaviour. In this case, the temperature dependence of the magnetization measured after zero magnetic field cooling deviates from the magnetization measured after magnetic field cooling protocol, which proves that the strain glass behaviour induces non-ergodicity in the magnetic degrees of freedom as well. Lloveras et al. study a model for systems undergoing a magnetostructural transition that combines a Ginzburg-Landau free energy accounting for the structural contribution together with a micromagnetic term that describes the magnetic and magnetostructural contributions. Both strain and magnetic glass behaviour is predicted to occur in off-stoichiometric magnetic shape-memory materials with low elastic anisotropy.
Author Porta, Marcel
Planes, Antoni
Saxena, Avadh
Lloveras, Pol
Castán, Teresa
Lookman, Turab
Touchagues, Gilles
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Snippet In this paper, we propose a model that combines a Landau free energy part and a micromagnetic free energy part aimed at describing a magnetostructural...
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SubjectTerms Anisotropy
Energies
Enginyeria dels materials
Free energy
Glass
Magnetic glass
Magnetic materials
Magnetic shape memory
Magnetism
Magnetisme
Magnetization
Martensitic transition
Materials funcionals
Materials magnètics
Mathematical models
Shape memory
Strain
Strain glass
Texture
Àrees temàtiques de la UPC
Title Modelling magnetostructural textures in magnetic shape-memory alloys: Strain and magnetic glass behaviour
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https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fpssb.201350394
https://search.proquest.com/docview/1629344563
https://recercat.cat/handle/2072/244867
Volume 251
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