Your search keyword '"Stone KH"' showing total 3 results

1. Temperature-driven growth of antiferromagnetic domains in thin-film FeRh.

Author

Baldasseroni, C, Bordel, C, Antonakos, C, Scholl, A, Stone, KH, Kortright, JB, and Hellman, F

Subjects

magnetic films, magnetic phase transitions, XMLD, Fluids & Plasmas, Condensed Matter Physics, Materials Engineering, Nanotechnology

Abstract

The evolution of the antiferromagnetic phase across the temperature-driven ferromagnetic (FM) to antiferromagnetic (AF) phase transition in epitaxial FeRh thin films was studied by x-ray magnetic linear and circular dichroism (XMLD and XMCD) and photoemission electron microscopy. By comparing XMLD and XMCD images recorded at the same temperature, the AF phase was identified, its structure directly imaged, and its evolution studied across the transition. A quantitative analysis of the correlation length of the images shows differences between the characteristic length scale of the two phases with the AF phase having a finer feature size. The asymmetry of the transition from FM to AF upon cooling and AF-FM upon heating is evidenced: upon cooling the formation of AF phase is dominated by nucleation at defects, with little subsequent growth, resulting in a small and non-random final AF domain structure, while upon heating, heterogeneous nucleation at different sites followed by significant domain size growth of the FM phase is observed, resulting in a non-reproducible final FM large domain structure.

Published

2015

2. Effect of chemical order on the magnetic and electronic properties of epitaxial off-stoichiometry FexSi1−x thin films

Author

Karel, J, Juraszek, J, Minar, J, Bordel, C, Stone, KH, Zhang, YN, Hu, J, Wu, RQ, Ebert, H, Kortright, JB, and Hellman, F

Subjects

Physical Sciences, Condensed Matter Physics, Chemical sciences, Engineering, Physical sciences

Abstract

Off-stoichiometry, epitaxial FexSi1-x thin films (0.5 < x < 1.0) exhibit D03 or B2 chemical order, even far from stoichiometry. Theoretical calculations show the magnetic moment is strongly enhanced in the fully chemically disordered A2 phase, while both theoretical and experimental results show that the magnetization is nearly the same in the B2 and D03 phases, meaning partial chemical disorder does not influence the magnetism. The dependencies of the magnetic moments are directly and nonlinearly linked to the number of Si atoms, primarily nearest neighbor but also to a lesser extent (up to 10%) next nearest neighbor, surrounding Fe, explaining the similarities between B2 and D03 and the strong enhancement for the A2 structure. The calculated electronic density of states shows many similarities in both structure and spin polarization between the D03 and B2 structures, while the A2 structure exhibits disorder broadening and a reduced spin polarization.

Published

2015

3. 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