Domain wall dynamics in cubic magnetostrictive materials subject to Rashba effect and nonlinear dissipation

This work focuses on the analytical investigation of domain wall motion occurring along the major axis of a thin magnetostrictive nanostrip perfectly arranged on the top of a thick piezoelectric actuator. The motion is driven by magnetic fields, spin-polarized currents, and spin–orbit torque effects...

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Published inZeitschrift für angewandte Mathematik und Physik Vol. 74; no. 1
Main Authors Maity, Sumit, Dolui, Sarabindu, Dwivedi, Sharad, Consolo, Giancarlo
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.02.2023
Springer Nature B.V
Subjects
Chemical composition
Dissipation
Domain walls
Engineering
Magnetic domains
Magnetostriction
Mathematical Methods in Physics
Piezoelectric actuators
Qualitative analysis
Theoretical and Applied Mechanics
Spin-transfer torque
Rashba effect
74E15
Magnetostriction
Dry-friction dissipation
Extended Landau–Lifshitz–Gilbert equation
Domain walls
74F99
82D40
Crystal symmetry
35C07
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Abstract This work focuses on the analytical investigation of domain wall motion occurring along the major axis of a thin magnetostrictive nanostrip perfectly arranged on the top of a thick piezoelectric actuator. The motion is driven by magnetic fields, spin-polarized currents, and spin–orbit torque effects and takes place in cubic magnetostrictive materials characterized by a nonlinear dissipation. The main aim is to describe how magnetoelasticity, Rashba field, dry-friction , chemical composition, and crystal symmetry affect the steady and precessional dynamics of magnetic domain walls. In detail, it is here analytically inspected how the key features (threshold, breakdown, domain wall mobility, and propagation direction) can be effectively manipulated by the above contributions. Finally, the theoretical results are numerically illustrated for realistic materials, revealing a satisfying qualitative agreement with experimental observations.
AbstractList This work focuses on the analytical investigation of domain wall motion occurring along the major axis of a thin magnetostrictive nanostrip perfectly arranged on the top of a thick piezoelectric actuator. The motion is driven by magnetic fields, spin-polarized currents, and spin–orbit torque effects and takes place in cubic magnetostrictive materials characterized by a nonlinear dissipation. The main aim is to describe how magnetoelasticity, Rashba field, dry-friction , chemical composition, and crystal symmetry affect the steady and precessional dynamics of magnetic domain walls. In detail, it is here analytically inspected how the key features (threshold, breakdown, domain wall mobility, and propagation direction) can be effectively manipulated by the above contributions. Finally, the theoretical results are numerically illustrated for realistic materials, revealing a satisfying qualitative agreement with experimental observations.
This work focuses on the analytical investigation of domain wall motion occurring along the major axis of a thin magnetostrictive nanostrip perfectly arranged on the top of a thick piezoelectric actuator. The motion is driven by magnetic fields, spin-polarized currents, and spin–orbit torque effects and takes place in cubic magnetostrictive materials characterized by a nonlinear dissipation. The main aim is to describe how magnetoelasticity, Rashba field, dry-friction, chemical composition, and crystal symmetry affect the steady and precessional dynamics of magnetic domain walls. In detail, it is here analytically inspected how the key features (threshold, breakdown, domain wall mobility, and propagation direction) can be effectively manipulated by the above contributions. Finally, the theoretical results are numerically illustrated for realistic materials, revealing a satisfying qualitative agreement with experimental observations.
ArticleNumber 23
Author Dolui, Sarabindu
Consolo, Giancarlo
Maity, Sumit
Dwivedi, Sharad
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  surname: Maity
  fullname: Maity, Sumit
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  givenname: Sarabindu
  surname: Dolui
  fullname: Dolui, Sarabindu
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  givenname: Sharad
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  surname: Dwivedi
  fullname: Dwivedi, Sharad
  email: sharad@nitandhra.ac.in
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  givenname: Giancarlo
  orcidid: 0000-0002-6368-8733
  surname: Consolo
  fullname: Consolo, Giancarlo
  organization: Department of Mathematics, Computer, Physical and Earth Sciences, University of Messina
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Issue 1
Keywords Spin-transfer torque
Rashba effect
74E15
Magnetostriction
Dry-friction dissipation
Extended Landau–Lifshitz–Gilbert equation
Domain walls
74F99
82D40
Crystal symmetry
35C07
Language English
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PublicationSubtitle Journal of Applied Mathematics and Physics / Journal de Mathématiques et de Physique appliquées
PublicationTitle Zeitschrift für angewandte Mathematik und Physik
PublicationTitleAbbrev Z. Angew. Math. Phys
PublicationYear 2023
Publisher Springer International Publishing
Springer Nature B.V
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Snippet This work focuses on the analytical investigation of domain wall motion occurring along the major axis of a thin magnetostrictive nanostrip perfectly arranged...
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SubjectTerms Chemical composition
Dissipation
Domain walls
Engineering
Magnetic domains
Magnetostriction
Mathematical Methods in Physics
Piezoelectric actuators
Qualitative analysis
Theoretical and Applied Mechanics
Title Domain wall dynamics in cubic magnetostrictive materials subject to Rashba effect and nonlinear dissipation
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