Title :
Intrinsic and Thermal Linewidths of Spin-Transfer-Driven Vortex Self-Oscillations
Author :
Torres, L. ; Carpentieri, Michele ; Martinez, E. ; Lopez-Diaz, L. ; Hernandez-Lopez, A. ; Aurelio, D. ; Finocchio, Giovanni
Author_Institution :
Dept. de Fis. Aplic., Univ. de Salamanca, Salamanca, Spain
Abstract :
Narrow linewidth spin transfer driven vortex self-oscillations in Py/Cu/Py spin valves of elliptical cross section (160 nm × 75 nm) are investigated by means of micromagnetic simulations. “GPmagnet”, a high performance GPU based micromagnetic package, is used for this purpose, allowing for 100 KHz spectral resolution at reasonable computational time. The variation of the linewidth with applied current (10 × 107 A/cm2 A/cm2 <; J <; 20 × 107 A/cm2) is analyzed in the temperature range 0 K <; K <; 300 K. Linewidths around 1 MHz are found at T = 0K. At T = 300 K, linewidths remain below 2 MHz for J <; 16 × 107 A/cm2, whereas for larger currents the presence of two oscillation modes lead to a further linewidth increase.
Keywords :
graphics processing units; magnetoelectronics; micromagnetics; oscillations; oscillators; spin valves; GPmagnet; applied current; elliptical cross section; high performance GPU based micromagnetic package; intrinsic linewidth; micromagnetic simulations; narrow linewidth spin transfer driven vortex self-oscillations; oscillation modes; spectral resolution; spin valves; temperature 0 K; temperature 300 K; thermal linewidth; Harmonic analysis; Micromagnetics; Noise; Oscillators; Temperature dependence; Thermal noise; Torque; Linewidths; micromagnetic model; spin torque nano-oscillators (STNO); thermal activation;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2248135
