MAGNETOELECTRIC EFFECT INDUCED BY ORBITAL ORDERING OF ELECTRONS


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Abstract

Relationship between orbital order and the formation of the spontaneous magnetic moment, lattice constant, correlation function of orbital and spin moments between nearest neighbors have been investigated in terms of the continuous Potts model for set of electron-phonon parameters and spin-phonon interactions. A change in the permittivity and orbital correlation functions in the external magnetic field has been found.

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The study of multiferroics with the coexistence of at least two of the three order parameters (magnetic, electric, and crystallographic) [1] is an urgent problem, for it describes the possibility of controlling the magnetic properties of a material by means of an electric-field and, vice versa, magnetic-field modulation of electric properties. In the future, multiferroics may find wide technical application in sensors and recording devices, reading and storing information. While the spintronic devices transform information by changing the magnetization to electric voltage; in multiferroics the correlation between the magnetic and electric subsystems manifests itself in the magnetoelectric effect [2; 3]. The CoxMn1–xS solid solutions can be attributed to the multiferroic class [4]. In the temperature ranges of T ≈ 110–120 K and T ≈ 230–260 K, the correlation between the magnetic and electric subsystems has been found [5]. The presence of this correlation is confirmed by sharp rise of the magnetization and the maximum in the relative variation of permittivity, measured in the external magnetic field and without it at a lowering temperature [6].
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About the authors

S. S. Aplesnin

Siberian State Aerospace University named after academician M. F. Reshetnev

Russia, Krasnoyarsk

A. I. Moskvin

Siberian State Aerospace University named after academician M. F. Reshetnev

Russia, Krasnoyarsk

References

  1. Epitaxial BiFeO3 Multiferroic Thin Film Heterostructures / J. Wang [et al.] // Science. 2003. Vol. 209. P. 1719–1728.
  2. Zvesdin A. К., Pyatakov А. P. Phase transition and colossal magnetoelectric effect // UFN. 2004. Vol. 174. P. 465–468.
  3. Smirnov А. I., Hlusticov I. N. Magnetoelectric effect and Stark effect // UFN. 1995. Vol. 165. P. 1215–1219.
  4. Transport Properties and Ferromagnetism of CoxMn1–xS Sulfides / S. S. Aplesnin [et al.] // JETF. 2008. Vol. 106, № 4. P. 765–772.
  5. Magnetoelectric effect in CoxMn1–xS S. S. Aplesnin [et al.] // Vestnic of SibSAU. 2009. Vol. 1(22). P. 41–45.
  6. Spin Glass Effects in CoxMn1–xS Solid Solutions S. S. Aplesnin [et al.] // Bulletin of the Russian Academy of Sciences: Physics. 2009. Vol. 73, № 7. P. 965–967.

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Copyright (c) 2010 Aplesnin S.S., Moskvin A.I.

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