Title :
Properties of ferromagnetic Ga1-xMnxN films grown by ammonia-MBE
Author :
Sonoda, Saki ; Hori, Hidenobu ; Yamamoto, Yoshiyuki ; Sasaki, Takahiko ; Sato, Masugu ; Shimizu, Saburo ; Suga, Ken-ichi ; Kindo, Koichi
Author_Institution :
ULVAC Inc., Kanagawa, Japan
fDate :
9/1/2002 12:00:00 AM
Abstract :
Using ammonia as nitrogen source for molecular beam epitaxy, the GaN-based diluted magnetic semiconductor Ga1-xMnxN is successfully grown with Mn concentration up to x∼6.8% and with p-type conductivity. The films have wurtzite structure with substitutional Mn on Ga site in GaN. Magnetization measurements revealed that Ga1-xMnxN is ferromagnetic at temperatures higher than room temperature. The ferromagnetic-paramagnetic transition temperature, Tc, depends on the Mn concentration of the film. At low temperatures, the magnetization increases with increasing of magnetic field, implying that a paramagnetic-like phase coexists with ferromagnetic one. Possible explanations will be proposed for the coexistence of two magnetic phases in the grown films.
Keywords :
Curie temperature; EXAFS; III-V semiconductors; chemical beam epitaxial growth; electrical conductivity; ferromagnetic materials; ferromagnetic-paramagnetic transitions; gallium compounds; magnetic epitaxial layers; magnetic hysteresis; manganese compounds; paramagnetic resonance; reflection high energy electron diffraction; semiconductor epitaxial layers; semimagnetic semiconductors; spontaneous magnetisation; wide band gap semiconductors; Curie temperature; EXAFS; GaMnN; M-H curves; RHEED; ammonia source molecular beam epitaxy; concentration dependences; diluted magnetic semiconductor; electron spin resonance; ferromagnetic films; ferromagnetic-paramagnetic transition temperature; hysteresis loops; lattice constants; local lattice configuration; magnetization; p-type conductivity; spontaneous magnetization; temperature dependence; wide-gap semiconductors; wurtzite structure; Conductivity; Gallium nitride; Magnetic field measurement; Magnetic films; Magnetic semiconductors; Magnetization; Molecular beam epitaxial growth; Nitrogen; Semiconductor films; Temperature;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2002.803147
