Room-temperature spin–orbit torque in NiMnSb

Materials that crystalize in diamond-related lattices, with Si and GaAs as their prime examples, are at the foundation of modern electronics. Simultaneously, the two atomic sites in the unit cell of these crystals form inversion partners which gives rise to relativistic non-equilibrium spin phenomena highly relevant for magnetic memories and other spintronic devices. When the inversion-partner sites are occupied by the same atomic species, electrical current can generate local spin polarization with the same magnitude and opposite sign on the two inversion-partner sites. In CuMnAs, which shares this specific crystal symmetry of the Si lattice, the effect led to the demonstration of electrical switching in an antiferromagnetic memory at room temperature. When the inversion-partner sites are occupied by different atoms, a non-zero global spin-polarization is generated by the applied current which can switch a ferro-magnet, as reported at low temperatures in the diluted magnetic semiconductor (Ga,Mn)As. Here we demonstrate the effect of the global current-induced spin polarization in a counterpart crystal-symmetry material NiMnSb which is a member of the broad family of magnetic Heusler compounds. It is an ordered high-temperature ferromagnetic metal whose other favorable characteristics include high spin-polarization and low damping of magnetization dynamics. Our experiments are performed on strained single-crystal epilayers of NiMnSb grown on InGaAs. By performing all-electrical ferromagnetic resonance measurements in microbars patterned along different crystal axes we detect room-temperature spin-orbit torques generated by effective fields of the Dresselhaus symmetry. The measured magnitude and symmetry of the current-induced torques are consistent with our relativistic density-functional theory calculations.

[1]  A. Rushforth,et al.  Electrical switching of an antiferromagnet , 2015, Science.

[2]  D. D. Awschalom,et al.  Observation of the Spin Hall Effect in Semiconductors , 2004, Science.

[3]  K. Buschow,et al.  Half-metallic ferromagnets. I. Structure and magnetic properties of NiMnSb and related inter-metallic compounds , 1989 .

[4]  S. Bandiera,et al.  Perpendicular switching of a single ferromagnetic layer induced by in-plane current injection , 2011, Nature.

[5]  J. Wunderlich,et al.  Spin-orbit-driven ferromagnetic resonance. , 2010, Nature nanotechnology.

[6]  K. Xia,et al.  First-principles scattering matrices for spin transport , 2005, cond-mat/0508373.

[7]  M. Harder,et al.  Analysis of the line shape of electrically detected ferromagnetic resonance , 2011, 1105.3236.

[8]  J. Artman Ferromagnetic Resonance in Metal Single Crystals , 1957 .

[9]  Spin splitting and spin current in strained bulk semiconductors , 2004, cond-mat/0408442.

[10]  L. Molenkamp,et al.  Control of the magnetic in-plane anisotropy in off-stoichiometric NiMnSb , 2013, 1312.4781.

[11]  Jairo Sinova,et al.  Experimental observation of the spin-Hall effect in a two-dimensional spin-orbit coupled semiconductor system. , 2005 .

[12]  M. Otto,et al.  Half-metallic ferromagnets. II. Transport properties of NiMnSb and related inter-metallic compounds , 1989 .

[13]  T. Hahn International Tables for Crystallography: Space-group symmetry , 2006 .

[14]  R. Hey,et al.  Current-induced spin polarization at a single heterojunction , 2004 .

[15]  Aurelien Manchon,et al.  Nonequilibrium intrinsic spin torque in a single nanomagnet , 2008 .

[16]  D. Ralph,et al.  Spin-Torque Switching with the Giant Spin Hall Effect of Tantalum , 2012, Science.

[17]  S. D. Ganichev,et al.  Magneto-gyrotropic effects in semiconductor quantum wells , 2008, 0803.0949.

[18]  J. Hirsch Spin Hall Effect , 1999, cond-mat/9906160.

[19]  Zhe Yuan,et al.  First-principles calculations of magnetization relaxation in pure Fe, Co, and Ni with frozen thermal lattice disorder , 2011, 1102.5305.

[20]  C. Kumpf,et al.  Structural and magnetic properties of NiMnSb/InGaAs/InP(001) , 2005 .

[21]  M. Farle Ferromagnetic resonance of ultrathin metallic layers , 1998 .

[22]  Mikhail I. Dyakonov Spin physics in semiconductors , 2008 .

[23]  Jacek K. Furdyna,et al.  Evidence for reversible control of magnetization in a ferromagnetic material by means of spin–orbit magnetic field , 2008, 0812.3160.

[24]  J. Artman Microwave Resonance Relations in Anisotropic Single Crystal Ferrites , 1956, Proceedings of the IRE.

[25]  T. Jungwirth,et al.  Complementary spin-Hall and inverse spin-galvanic effect torques in a ferromagnet/semiconductor bilayer , 2015, Nature Communications.

[26]  J. Nozieres,et al.  Half metallic NiMnSb-based spin-valve structures , 1998 .

[27]  F. Freimuth,et al.  Spin-orbit torques in Co/Pt(111) and Mn/W(001) magnetic bilayers from first principles , 2013, 1305.4873.

[28]  J. Sinova,et al.  An antidamping spin-orbit torque originating from the Berry curvature. , 2014, Nature nanotechnology.

[29]  A. Gossard,et al.  Current-induced spin polarization in strained semiconductors. , 2004, Physical review letters.

[30]  A. Zunger,et al.  Hidden spin polarization in inversion-symmetric bulk crystals , 2014, Nature Physics.

[31]  F. Freimuth,et al.  Symmetry and magnitude of spin-orbit torques in ferromagnetic heterostructures. , 2013, Nature nanotechnology.

[32]  J. Sinova,et al.  Spin Hall effects , 2015 .

[33]  S. Yuasa,et al.  Spin-torque diode effect in magnetic tunnel junctions , 2005, Nature.

[34]  D. Ralph,et al.  Spin-torque ferromagnetic resonance induced by the spin Hall effect. , 2010, Physical review letters.

[35]  J. Sinova,et al.  Relativistic Néel-order fields induced by electrical current in antiferromagnets. , 2014, Physical review letters.