Your search keyword '"Stone KH"' showing total 2 results

1. Using structural disorder to enhance the magnetism and spin-polarization in FexSi1-x thin films for spintronics

Author

Karel, J, Zhang, YN, Bordel, C, Stone, KH, Chen, TY, Jenkins, CA, Smith, DJ, Hu, J, Wu, RQ, Heald, SM, Kortright, JB, and Hellman, F

Subjects

amorphous, thin film magnetism, spintronics, x-ray absorption, x-ray magnetic circular dichroism, density functional theory, Materials Engineering

Abstract

Amorphous FexSi1-x thin films exhibit a striking enhancement in magnetization compared to crystalline films with the same composition (0.45 < x < 0.75), and xray magnetic circular dichroism reveals an enhancement in both spin and orbital moments in the amorphous films. Density functional theory (DFT) calculations reproduce this enhanced magnetization and also show a relatively large spinpolarization at the Fermi energy, also seen experimentally in Andreev reflection. Theory and experiment show that the amorphous materials have a decreased number of nearest neighbors and reduced number density relative to the crystalline samples of the same composition; the associated decrease in Fe-Si neighbors reduces the hybridization of Fe orbitals, leading to the enhanced moment.

Published

2014

2. Using structural disorder to enhance the magnetism and spin-polarization in Fe x Si1???x thin films for spintronics

Author

Karel, J, Zhang, YN, Bordel, C, Stone, KH, Chen, TY, Jenkins, CA, Smith, David J, Hu, J, Wu, RQ, Heald, SM, Kortright, JB, and Hellman, F

Subjects

Physical Sciences, Condensed Matter Physics, amorphous, thin film magnetism, spintronics, x-ray absorption, x-ray magnetic circular dichroism, density functional theory, Materials Engineering, Materials engineering, Condensed matter physics

Abstract

Amorphous FexSi1-x thin films exhibit a striking enhancement in magnetization compared to crystalline films with the same composition (0.45 < x < 0.75), and xray magnetic circular dichroism reveals an enhancement in both spin and orbital moments in the amorphous films. Density functional theory (DFT) calculations reproduce this enhanced magnetization and also show a relatively large spinpolarization at the Fermi energy, also seen experimentally in Andreev reflection. Theory and experiment show that the amorphous materials have a decreased number of nearest neighbors and reduced number density relative to the crystalline samples of the same composition; the associated decrease in Fe-Si neighbors reduces the hybridization of Fe orbitals, leading to the enhanced moment.

Published

2014