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Magnetic and electric properties of double-perovskites and estimation of their Curie temperatures by ab initio calculations

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arxiv 0807.4689 v2 pith:5TI3RCI4 submitted 2008-07-29 cond-mat.mtrl-sci cond-mat.other

Magnetic and electric properties of double-perovskites and estimation of their Curie temperatures by ab initio calculations

classification cond-mat.mtrl-sci cond-mat.other
keywords curietemperaturesapproximationoxygenatomscalculationselectronicelectrons
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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First principles electronic structure calculations have been carried out on ordered double perovskites Sr_2B'B"O_6 (for B' = Cr or Fe and B" 4d and 5d transition metal elements) with increasing number of valence electrons at the B-sites, and on Ba_2MnReO_6 as well as Ba_2FeMoO_6. The Curie temperatures are estimated ab initio from the electronic structures obtained with the local spin-density functional approximation, full-potential generalized gradient approximation and/or the LDA+U method (U - Hubbard parameter). Frozen spin-spirals are used to model the excited states needed to evaluate the spherical approximation for the Curie temperatures. In cases, where the induced moments on the oxygen was found to be large, the determination of the Curie temperature is improved by additional exchange functions between the oxygen atoms and between oxygen and B' and B" atoms. A pronounced systematics can be found among the experimental and/or calculated Curie temperatures and the total valence electrons of the transition metal elements.

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