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Magnetoresistance from quantum interference effects in ferromagnets

Author

Listed:
  • N. Manyala

    (Department of Physics and Astronomy Louisiana State University)

  • Y. Sidis

    (Department of Physics and Astronomy Louisiana State University
    Laboratoire L’eon Brillouin, CEA-CNRS, CE Saclay)

  • J. F. DiTusa

    (Department of Physics and Astronomy Louisiana State University)

  • G. Aeppli

    (NEC)

  • D.P. Young

    (National High Magnetic Field Facility, Florida State University)

  • Z. Fisk

    (National High Magnetic Field Facility, Florida State University)

Abstract

The desire to maximize the sensitivity of read/write heads (and thus the information density) of magnetic storage devices has stimulated interest in the discovery and design of new magnetic materials exhibiting magnetoresistance. Recent discoveries include the ‘colossal’ magnetoresistance in the manganites1,2,3,4 and the enhanced magnetoresistance in low-carrier-density ferromagnets4,5,6. An important feature of these systems is that the electrons involved in electrical conduction are different from those responsible for the magnetism. The latter are localized and act as scattering sites for the mobile electrons, and it is the field tuning of the scattering strength that ultimately gives rise to the observed magnetoresistance. Here we argue that magnetoresistance can arise by a different mechanism in certain ferromagnets—quantum interference effects rather than simple scattering. The ferromagnets in question are disordered, low-carrier-density magnets where the same electrons are responsible for both the magnetic properties and electrical conduction. The resulting magnetoresistance is positive (that is, the resistance increases in response to an applied magnetic field) and only weakly temperature-dependent below the Curie point.

Suggested Citation

  • N. Manyala & Y. Sidis & J. F. DiTusa & G. Aeppli & D.P. Young & Z. Fisk, 2000. "Magnetoresistance from quantum interference effects in ferromagnets," Nature, Nature, vol. 404(6778), pages 581-584, April.
    • Handle: RePEc:nat:nature:v:404:y:2000:i:6778:d:10.1038_35007030
    DOI: 10.1038/35007030
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