Your search keyword '"Chshiev, M."' showing total 2 results

1. Voltage Dependence of Spin Transfer Torque In Magnetic Tunnel Junctions.

Author

Chshiev, M., Theodonis, I., Kalitsov, A., Kioussis, N., and Butler, W. H.

Subjects

*SPINTRONICS, *SEMICONDUCTOR junctions, *MAGNETIC coupling, *QUANTUM tunneling, *QUANTUM teleportation, *TORQUE, *FERMI surfaces

Abstract

Theoretical investigations of spin transfer torque in magnetic tunnel junctions using the tight-binding model in the framework of nonequilibrium Green functions formalism are presented. We show that the behavior of the spin transfer torque as a function of applied voltage can vary over a wide range depending on the band parameters of the ferromagnetic electrodes and the insulator that comprise the magnetic tunnel junction. The behavior of both the parallel and perpendicular components of the spin torque is addressed. This behavior is explained in terms of the spin and charge current dependence and on the interplay between evanescent states in the insulator and the Fermi surfaces of ferromagnetic electrodes comprising the junction. The origin of the perpendicular (field-like) component of spin transfer torque at zero bias, i.e., exchange coupling through the barrier between ferromagnetic electrodes is discussed. [ABSTRACT FROM AUTHOR]

Published

2008

2. Theory of Tunneling Magnetoresistance for Epitaxial Systems.

Author

Butler, W. H., X.-G. Zhang, Vutukuri, S., Chshiev, M., and Schulthess, T. C.

Subjects

*MAGNETIC fields, *ELECTRIC resistance, *QUANTUM tunneling, *PARTICLES (Nuclear physics), *CATHODE rays, *ELECTRIC resistors

Abstract

The tunneling current for electrons tunneling between crystalline ferromagnetic electrodes through an epitaxial crystalline barrier can be calculated from first principles. These calculations show that the wave function symmetry can be exploited to achieve very high tunneling magnetoresistance. For the Fe(100)∣MgO(100) ∣Fe(100) system, the calculated conductance is much higher and its decrease with MgO thickness is much slower than has been estimated using a simple free electron-barrier model. [ABSTRACT FROM AUTHOR]

Published

2005