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Towards a new class of heavy ion doped magnetic semiconductors for room temperature applications.


ABSTRACT: The article presents, using Bi doped ZnO, an example of a heavy ion doped oxide semiconductor, highlighting a novel p-symmetry interaction of the electronic states to stabilize ferromagnetism. The study includes both ab initio theory and experiments, which yield clear evidence for above room temperature ferromagnetism. ZnBi(x)O(1-x) thin films are grown using the pulsed laser deposition technique. The room temperature ferromagnetism finds its origin in the holes introduced by the Bi doping and the p-p coupling between Bi and the host atoms. A sizeable magnetic moment is measured by means of x-ray magnetic circular dichroism at the O K-edge, probing directly the spin polarization of the O(2p) states. This result is in agreement with the theoretical predictions and inductive magnetometry measurements. Ab initio calculations of the electronic and magnetic structure of ZnBi(x)O(1-x) at various doping levels allow to trace the origin of the ferromagnetic character of this material. It appears, that the spin-orbit energy of the heavy ion Bi stabilizes the ferromagnetic phase. Thus, ZnBi(x)O(1-x) doped with a heavy non-ferromagnetic element, such as Bi, is a credible example of a candidate material for a new class of compounds for spintronics applications, based on the spin polarization of the p states.

SUBMITTER: Lee J 

PROVIDER: S-EPMC4655408 | biostudies-literature | 2015 Nov

REPOSITORIES: biostudies-literature

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Towards a new class of heavy ion doped magnetic semiconductors for room temperature applications.

Lee Juwon J   Subramaniam Nagarajan Ganapathi NG   Kowalik Iwona Agnieszka IA   Nisar Jawad J   Lee Jaechul J   Kwon Younghae Y   Lee Jaechoon J   Kang Taewon T   Peng Xiangyang X   Arvanitis Dimitri D   Ahuja Rajeev R  

Scientific reports 20151123


The article presents, using Bi doped ZnO, an example of a heavy ion doped oxide semiconductor, highlighting a novel p-symmetry interaction of the electronic states to stabilize ferromagnetism. The study includes both ab initio theory and experiments, which yield clear evidence for above room temperature ferromagnetism. ZnBi(x)O(1-x) thin films are grown using the pulsed laser deposition technique. The room temperature ferromagnetism finds its origin in the holes introduced by the Bi doping and t  ...[more]

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