Title :
Assessment of Rashba Field Effects in Ultrathin Pt/Co/GdOx Submicrometer Strips
Author :
Emori, S. ; Beach, G.S.D.
Author_Institution :
Dept. of Mater. Sci. & Eng., Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
The influence of injected current on magnetization dynamics is investigated in submicrometer-wide strips of out-of-plane magnetized Pt/Co/GdOx. This ultrathin film structure is similar to Pt/Co/AlOx exhibiting highly efficient current-driven domain wall (DW) motion, which has recently been attributed in part to the Rashba effect. In Pt/Co/GdOx, the reduction of the out-of-plane magnetization with increasing injected current is largely due to Joule heating, and the effective transverse Rashba field that tilts the magnetization is estimated to be at most ~0.3 T/(1012 A/m2). Measurements of high-speed DW motion reveal no evidence of a strong Rashba field to suppress DW precession. These findings indicate that the Rashba effect plays a limited or negligible role in current-driven DW dynamics, and alternative torques are required to explain the high efficiency of DW motion in ultrathin heavy-metal/ferromagnet/oxide systems.
Keywords :
cobalt; ferromagnetic materials; gadolinium compounds; heating; magnetic domain walls; magnetic multilayers; magnetic thin films; magnetisation; platinum; silicon; silicon compounds; strips; tantalum; torque; Joule heating; Si-SiO2-Ta-Pt-Co-GdOx; alternative torques; high-speed current-driven domain wall motion; injected current; magnetization dynamics; out-of-plane magnetization; transverse Rashba field effects; ultrathin film structure; ultrathin heavy-metal-ferromagnet-oxide systems; ultrathin submicrometer strips; Current density; Magnetization; Perpendicular magnetic anisotropy; Strips; Temperature measurement; Magnetic domain walls; magnetic multilayers; magnetoelectronics; perpendicular magnetic anisotropy;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2251459
