An electric current in the presence of spin-orbit coupling can generate a spin accumulation that exerts torques on a nearby magnetization. We demonstrate that, even in the absence of materials with strong bulk spin-orbit coupling, a torque can arise solely due to interfacial spin-orbit coupling, namely Rashba-Eldestein effects at metal/insulator interfaces. In magnetically soft NiFe sandwiched between a weak spin-orbit metal (Ti) and insulator (Al2O3), this torque appears as an effective field, which is significantly larger than the Oersted field and sensitive to insertion of an additional layer between NiFe and Al2O3. Our findings point to new routes for tuning spin-orbit torques by engineering interfacial electric dipoles.
@article{arxiv.1601.07687,
title = {Interfacial spin-orbit torque without bulk spin-orbit coupling},
author = {Satoru Emori and Tianxiang Nan and Amine M. Belkessam and Xinjun Wang and Alexei D. Matyushov and Christopher J. Babroski and Yuan Gao and Hwaider Lin and Nian X. Sun},
journal= {arXiv preprint arXiv:1601.07687},
year = {2016}
}