Title :
Thermally-Assisted Spin-Transfer Torque Magnetization Reversal of Uniaxial Nanomagnets in Energy Space
Author :
Pinna, D. ; Ken, A.D. ; Stein, D.L.
Author_Institution :
Dept. of Phys., New York Univ., New York, NY, USA
Abstract :
We propose a new analytical method for studying the asymptotic behavior of switching time as a function of current in macrospins under the effects of both spin-torque and thermal noise by focusing on their diffusive energy space dynamics. We test our method on the well understood uniaxial macrospin model and confirm the switching scaling dependence (I → 0,(τ)∝ exp(-ξ(1-I)2)). The analysis also shows that when there is an angle between spin current and magnet´s uniaxial axes the mean switching time in the low current limit depends on the spin-current projection on the easy axis, but otherwise has the same functional form as that in the collinear case. These results have implications for modeling the energetics of thermally assisted magnetization reversal of spin transfer magnetic random access memory bit cells.
Keywords :
MRAM devices; magnetic switching; magnetisation reversal; nanomagnetics; spin dynamics; spin systems; thermal noise; asymptotic behavior; collinear case; diffusive energy space dynamics; energetic modelling; energy space; magnet uniaxial axis; material testing; spin current function; spin transfer magnetic random access memory bit cells; spin-current projection; spin-torque noise; switching scaling dependence; switching time; thermal noise; thermally-assisted spin-transfer torque magnetization reversal; uniaxial macrospin model; uniaxial nanomagnets; Anisotropic magnetoresistance; Equations; Magnetomechanical effects; Mathematical model; Noise; Perpendicular magnetic anisotropy; Magnetic memory; micromagnetics; spin-transfer magnetic memory; thermal noise;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2239266
