Title :
Magnetic behavior of single crystal epilayers of the diluted magnetic semiconductor Zn1-xCoxSe
Author :
Krebs, J.J. ; Jonker, B.T. ; Prinz, G.A.
Author_Institution :
US Naval Res. Lab., Washington, DC, USA
fDate :
11/1/1988 12:00:00 AM
Abstract :
SQUID magnetometry (6-100 K, 4 Tesla) and 9.3-GHz EPR studies have been carried out on thin single-crystal films as a function of Co concentration for 0.0076⩽x⩽0.094. The samples were grown by molecular beam epitaxy on GaAs(001) substrates and were characterized by RHEED. X-ray fluorescence, and several X-ray diffraction techniques. At low temperatures the magnetic behavior is dominated by the isolated paramagnetic Co2+ ions (S=3/2) in Zn sites. The reduction of the measured magnetization from the calculated magnetization shows that nn (and perhaps nnn) Co2+ pairs are antiferromagnetically coupled with an exchange constant exceeding 20 K. For higher x samples, EPR at 5 K gives an isotropic g=2.27 Co2+ line with an x-dependent linewidth. For x=0.0076, strong angularly dependent EPR lines are seen that are thought to arise from Co2+ ions in low-symmetry sites, probably in the neighborhood of dislocations. Their contribution to the magnetization also is reduced relative to isolated Co2+ ions
Keywords :
X-ray diffraction examination of materials; X-ray fluorescence analysis; cobalt compounds; magnetic epitaxial layers; magnetic semiconductors; magnetic thin films; molecular beam epitaxial growth; paramagnetic properties of substances; paramagnetic resonance of iron group ions and impurities; reflection high energy electron diffraction; semiconductor epitaxial layers; zinc compounds; 4 T; 5 to 100 K; 9.3 GHz; Co concentration; Co2+ pairs; EPR studies; GaAs substrates; GaAs(001) substrates; MBE; RHEED; SQUID magnetometry; X-ray diffraction; X-ray fluorescence; Zn1-xCoxSe; antiferromagnetic exchange constant; antiferromagnetically coupled; diluted magnetic semiconductor; electron paramagnetic resonance; low temperatures; magnetic behavior; magnetization; molecular beam epitaxy; single crystal epilayers; thin single-crystal films; Fluorescence; Magnetic films; Magnetization; Molecular beam epitaxial growth; Paramagnetic materials; Paramagnetic resonance; SQUIDs; Substrates; Temperature; X-ray diffraction;
Journal_Title :
Magnetics, IEEE Transactions on
