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Tunable magnetic anisotropy in multiferroic oxides
Xue Zeng Lu,
James M. Rondinelli
*
*
Corresponding author for this work
Materials Science and Engineering
Research output
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Contribution to journal
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Article
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peer-review
2
Scopus citations
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Physics
Electric Fields
100%
Oxide
100%
Magnetic Anisotropy
100%
Multiferroic
100%
Perpendicular Magnetic Anisotropy
75%
Plane
75%
Orbitals
50%
Ion
50%
Strain
50%
Perovskites
50%
First-Principles
25%
Room Temperature
25%
Magnetization
25%
Electric Potential
25%
Magnetism
25%
Electronic Structure
25%
Phase Transition
25%
Spin-Orbit Coupling
25%
Ferroelectricity
25%
Multiferroic Material
25%
Utilization
25%
Model
25%
Information
25%
Spin
25%
Technology
25%
Calculation
25%
Symmetry
25%
Rules
25%
Substrates
25%
Oxygen
25%
Competition
25%
Ferroelectricity
25%
Memory
25%
INIS
oxides
100%
anisotropy
100%
control
57%
electric fields
57%
strains
28%
ions
28%
hybrids
14%
design
14%
crystallography
14%
interactions
14%
devices
14%
information
14%
storage
14%
applications
14%
energy
14%
origin
14%
competition
14%
electronic structure
14%
substrates
14%
voltage
14%
spin
14%
temperature range 0273-0400 k
14%
relativistic range
14%
oxygen
14%
symmetry
14%
randomness
14%
phase transformations
14%
superlattices
14%
magnetism
14%
ferroelectric materials
14%
orbits
14%
perovskites
14%
magnetization
14%
perovskite
14%
l-s coupling
14%
Material Science
Oxide
100%
Anisotropy
100%
Perovskites
33%
Heterojunction
16%
Material
16%
Devices
16%
Electronic Structure
16%
Ferroelectric Material
16%
Temperature
16%
Magnetism
16%