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On the origin of high-temperature ferromagnetism in the low-temperature-processed Mn–Zn–O system.

Authors :
Kundaliya, Darshan C.
Ogale, S. B.
Lofland, S. E.
Dhar, S.
Metting, C. J.
Shinde, S. R.
Ma, Z.
Varughese, B.
Ramanujachary, K. V.
Salamanca-Riba, L.
Venkatesan, T.
Source :
Nature Materials; Oct2004, Vol. 3 Issue 10, p709-714, 6p, 3 Graphs
Publication Year :
2004

Abstract

The recent discovery of ferromagnetism above room temperature in low-temperature-processed MnO<subscript>2</subscript>–ZnO has generated significant interest. Using suitably designed bulk and thin-film studies, we demonstrate that the ferromagnetism in this system originates in a metastable phase rather than by carrier-induced interaction between separated Mn atoms in ZnO. The ferromagnetism persists up to ∼980 K, and further heating transforms the metastable phase and kills the ferromagnetism. By studying the interface diffusion and reaction between thin-film bilayers of Mn and Zn oxides, we show that a uniform solution of Mn in ZnO does not form under low-temperature processing. Instead, a metastable ferromagnetic phase develops by Zn diffusion into the Mn oxide. Direct low-temperature film growth of Zn-incorporated Mn oxide by pulsed laser deposition shows ferromagnetism at low Zn concentration for an optimum oxygen growth pressure. Our results strongly suggest that the observed ferromagnetic phase is oxygen-vacancy-stabilized Mn<subscript>2−x</subscript>Zn<subscript>x</subscript>O<subscript>3−δ.</subscript> [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
14761122
Volume :
3
Issue :
10
Database :
Complementary Index
Journal :
Nature Materials
Publication Type :
Academic Journal
Accession number :
18445610
Full Text :
https://doi.org/10.1038/nmat1221