His scientific interests lie mostly in Condensed matter physics, Magnetic semiconductor, Ferromagnetism, Curie temperature and Magnetization. The Condensed matter physics study combines topics in areas such as Thin film and Electrical resistivity and conductivity. His studies deal with areas such as Acceptor, Quasi Fermi level, Fermi level, Magnetoresistance and Magnetic susceptibility as well as Magnetic semiconductor.
He studies Spintronics which is a part of Ferromagnetism. K. W. Edmonds has included themes like Molecular beam epitaxy, Gallium arsenide and Analytical chemistry in his Curie temperature study. His study in Magnetization focuses on Magnetic anisotropy in particular.
His scientific interests lie mostly in Condensed matter physics, Ferromagnetism, Magnetic semiconductor, Magnetization and Magnetic anisotropy. His Curie temperature, Spintronics and Antiferromagnetism study in the realm of Condensed matter physics connects with subjects such as Anisotropy. His Ferromagnetism research includes themes of Magnetism, Magnetic circular dichroism, Ferroelectricity, Molecular beam epitaxy and Semiconductor.
His Magnetic semiconductor study incorporates themes from Gallium arsenide, Thin film, Hall effect, Electrical resistivity and conductivity and Analytical chemistry. He interconnects Magnetic moment and Voltage in the investigation of issues within Magnetization. His Magnetic anisotropy research is multidisciplinary, incorporating elements of Piezoelectricity, Magnetic hysteresis, Relaxation and Magnetostriction.
His primary areas of study are Condensed matter physics, Antiferromagnetism, Spintronics, Ferromagnetism and Magnetization. His Condensed matter physics research focuses on Spin-½ in particular. His Antiferromagnetism research integrates issues from Tetragonal crystal system, Domain wall and Magnetic moment.
His Spintronics research incorporates themes from Magnetometer, Hall effect, Electrical resistivity and conductivity and Magnetoresistance. Curie temperature is the focus of his Ferromagnetism research. In the subject of general Magnetization, his work in Remanence is often linked to Torque, thereby combining diverse domains of study.
K. W. Edmonds spends much of his time researching Condensed matter physics, Magnetization, Spintronics, Antiferromagnetism and Ferromagnetism. His research on Condensed matter physics focuses in particular on Spin-½. His Magnetization study combines topics in areas such as Rashba effect, Ferroelectricity and Voltage.
His research integrates issues of Optoelectronics and Printed circuit board in his study of Spintronics. As a part of the same scientific family, he mostly works in the field of Antiferromagnetism, focusing on Magnetic moment and, on occasion, Ampere and Lattice. K. W. Edmonds merges many fields, such as Ferromagnetism and Torque, in his writings.
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Electrical switching of an antiferromagnet
Peter Wadley;Bryn Howells;Jakub Zelezny;Carl Andrews.
arXiv: Mesoscale and Nanoscale Physics (2015)
Electrical switching of an antiferromagnet.
P. Wadley;Bryn Howells;J. Železný;J. Železný;C. Andrews.
Mn interstitial diffusion in (ga,mn)as.
K. W. Edmonds;P. Bogusławski;P. Bogusławski;K. Y. Wang;R. P. Campion.
Physical Review Letters (2004)
Prospects for high temperature ferromagnetism in (Ga,Mn)As semiconductors
T. Jungwirth;K. Y. Wang;J. Mašek;K. W. Edmonds.
Physical Review B (2005)
High-Curie-temperature Ga1−xMnxAs obtained by resistance-monitored annealing
K. W. Edmonds;K. Y. Wang;R. P. Campion;A. C. Neumann.
Applied Physics Letters (2002)
High Curie temperature GaMnAs obtained by resistance-monitored annealing
K.W. Edmonds;K.Y. Wang;R.P. Campion;A.C. Neumann.
arXiv: Materials Science (2002)
Electric field control of deterministic current-induced magnetization switching in a hybrid ferromagnetic/ferroelectric structure.
Kaiming Cai;Meiyin Yang;Hailang Ju;Sumei Wang.
Nature Materials (2017)
Electric field control of deterministic current-induced magnetization switching in a hybrid ferromagnetic/ferroelectric structure
Kaiming Cai;Meiyin Yang;Hailang Ju;Kevin William Edmonds.
arXiv: Materials Science (2016)
Achieving high Curie temperature in (Ga,Mn)As
M. Wang;R. P. Campion;A. W. Rushforth;K. W. Edmonds.
Applied Physics Letters (2008)
In-plane uniaxial anisotropy rotations in (Ga,Mn)As thin films
M. Sawicki;K.-Y. Wang;K. W. Edmonds;R. P. Campion.
Physical Review B (2005)
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