Title :
Magnetic Properties of Ge/MnAs Digital Heterostructure
Author :
Lee, J.J. ; Kim, M.Y. ; Song, J.H. ; Cui, Y. ; Ketterson, J.B.
Author_Institution :
Div. of Electr. & Comput. Eng., Ajou Univ., Suwon
fDate :
6/1/2007 12:00:00 AM
Abstract :
Magnetic properties of Ge/MnAs digital heterostructure grown by molecular beam epitaxy are reported. A Ge (1 nm)/MnAs (0.15 nm) digital heterostructure exhibited ferromagnetic ordering below 335 K. More importantly, the Ge (1 nm)/MnAs (0.15 nm) heterostructure shows an n-type conductivity and an anomalous Hall effect at room temperature. Concurrently, the magnetic phase stabilities of the Ge (1 nm)/MnAs (0.15 nm) digital heterostructure have been investigated using the highly precise all-electron full-potential linearized augmented plane-wave (FLAPW) method within the generalized gradient approximation (GGA). A total energy calculations reveal that the ferromagnetic coupling between the Mn atoms is energetically favored over the antiferromagnetic (100) and (110) coupling. The Ge (1 nm)/MnAs (0.15 nm) digital heterostructure also showed a possible half-metallic ferromagnetic phase with a 0.25 eV band gap for the minority spin channel, which indicates a promising possible spintronic application
Keywords :
APW calculations; Hall effect; electrical conductivity; elemental semiconductors; energy gap; ferromagnetic materials; germanium; gradient methods; interface magnetism; magnetic anisotropy; magnetic semiconductors; magnetoelectronics; manganese compounds; semiconductor heterojunctions; 0.15 nm; 1 nm; 293 to 298 K; FLAPW; GGA; Ge-MnAs; anomalous Hall effect; band gap; digital heterostructure; ferromagnetic ordering; full-potential linearized augmented plane-wave; generalized gradient approximation; magnetic anisotropy; magnetic phase stabilities; molecular beam epitaxy; n-type conductivity; room temperature; Conductivity; Gallium arsenide; III-V semiconductor materials; Magnetic materials; Magnetic multilayers; Magnetic properties; Molecular beam epitaxial growth; Physics; Temperature; X-ray diffraction; Anomalous Hall effect; digital heterostructure; half-metallicity; magnetic anisotropy;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2007.893701
