Spin as itinerant carrier of information A. Vedyayev, N. Ryzhanova, N. Strelkov (MSU) M. Chshiev, B. Dieny (Spintec, France)

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Presentation transcript:

Spin as itinerant carrier of information A. Vedyayev, N. Ryzhanova, N. Strelkov (MSU) M. Chshiev, B. Dieny (Spintec, France)

Scope Giant magnetoresistance (GMR) and tunnel magnetoresistance (TMR) as fundamental spintronics Current in plane (CIP) and current perpendicular to plane (CPP) GMR Mechanisms of GMR and TMR Spin torque. Applications of GMR and TMR ◦ Magnetic reading heads ◦ Magnetic random access memory (MRAM) ◦ Radio frequency oscillations RfO Spin Hall Effect (SHE) (Origin and possible applications) Conclusions

Giant magnetoresistance (GMR) Birth of spin electronics : Giant MagnetoResistance discovery (1988) M. N. Baibich, J. M. Broto, A. Fert et al Phys. Rev. Lett. 61, 2472–2475 (1988) G. Binasch, P. Grünberg et al Phys. Rev. B 39, 4828–4830 (1989) H=-H sat H=H sat H=0 GMR= R AP -R P RPRP GMR due to spin-dependent scattering in the bulk or at the interfaces of the magnetic layers

Giant magnetoresistance (GMR) Current In Plane (CIP) (Size effect) Current Perpendicular to Plane (CPP) Giant MagnetoResistance in Spin-valve structure GMR ~ e -t NM l NM r ~ 1/t sd ~ r d GMR = (r – r ) 2 2r r Dr ~ b 2 r 0 l sf

Tunnel magnetoresistance (TMR) Magnetic Tunnel Junctions and Tunnel MagnetoResistance Storage layer: CoFe – 4nm Al 2 O 3 barrier – 1.5nm Reference layer: CoFe – 3nm IrMn – 7nm Structure of a magnetic tunnel junction Acts as a couple polarizer/analyzer with the spin of the electrons. M. Julliere, Phys. Lett. A 54 (1975) J. S. Moodera et al, Phys. Rev. Lett. 74 (1995) Al(Zr)O x

Tunnel magnetoresistance (TMR) Giant Tunnel MagnetoResistance of MgO tunnel barriers S.S.P.Parkin et al, Nature Mat. (2004), nmat 1256 S.Yuasa et al, Nature Mat. (2004), nmat 1257 Very well textured MgO barriers grown by sputtering or MBE on bcc CoFe or Fe magnetic electrodes, or on amorphous CoFeB electrodes followed by annealing to recrystallize the electrode. S.Yuasa et al, Appl. Phys. Lett. 89 (2006)

` Spin Torque Spin torque in Magnetic Tunnel Junction (Ballistic mode) Spin Conf W. H. Butler et al, PHYSICAL REVIEW B, 63, Tunneling Density Of States

Spin Torque Spin torque in magnetic metallic multilayers (Diffusive mode) Charge current T. Valet and A. Fert Phys. Rev. B 48 (1993) Spin current Schematics of the mechanism of spin transfer torque in a metallic trilayer. Polarized electrons flowing from left to right precess around the right layer magnetization with different frequencies due to their different incident angles at the interface. This results in ballistic interference yielding an oscillation and damping of spin torque near the interface (typically 1 nm)

Spin Torque Spin torque and LLG equation m M Torque in plane (M, m) Torque perpendicular to plane (M, m) Torque perpendicular to plane (M, m)

Spin Torque Spin torque in magnetic metallic multilayers (Diffusive mode) Conditions for non-divergent current components Dependence of the spin torque on the coordinate X, perpendicular to the planes of the layers for the values of parameters depicted in table. Spin torque is given for parallel (solid line) and antiparallel (dotted line) configurations of the pinned layers. T is the spin torque in the free layer, averaged over its thickness. = -0.3 Oe = Oe = -0.3 Oe = Oe Material parameters used in the simulations. The interfacial resistance (r) and interfacial spin asymmetry ( γ ) are introduced for modeling CoFe/Cu interfaces:

Spin Torque Spin torque in magnetic metallic multilayers (Diffusive mode) Finite Element Modeling of Charge- and Spin-Currents N. Strelkov, A. Vedyayev et al, IEEE MAGNETICS LETTERS, Volume 1 (2010) Scheme of studied magnetoresistive nanopillar sandwiched between two extended electrodes. The nanopillar composition is a model sandwich of the form F3 nm/Cu2 nm/F3 nm in which F is a ferromagnetic metal. Zoom around the magnetoresistive pillar showing the y-component of spin current flow throughout the system in (a) parallel magnetic configuration, (b) antiparallel configuration. The normalized arrows indicate the spin current flow.

Spin Torque Spin torque in magnetic metallic multilayers (Diffusive mode) N. Strelkov, A. Vedyayev et al, PHYSICAL REVIEW B 84, (2011) Spin-current vortices in current-perpendicular-to-plane nanoconstricted spin valves Angular variation of the CPP-reduced resistance for the constriction of the 5-nm diameter and continuous spacer. The dots are the calculated values, and the lines are fits according to Slon- czewski’s expres- sion. In-plane and (b) perpendicular components of averaged spin- transfer torque over the whole volume of the “free” (right) magnetic layer as a function of the angle bet- ween the mag- netizations.

Spin Torque Spin torque in Magnetic Tunnel Junction (Ballistic mode) m y – Spin Transfer Torque (STT) m x – Interlayer Exchange Coupling (IEC) Keldysh Green function Y – Hartree-Fock spinor Schrödinger equation S d – local magnetization of d-electrons Spin torque definition =

Spin Torque Spin torque in Magnetic Tunnel Junction (Ballistic mode) Transfer spin density (black line) as a function of the distance in the left ferromagnetic electrode in a usual ferromagnetic regime. Total spin density as a function of the location in the left electrode. (a) Current-induced interlayer exchange coupling; inset, interlayer exchange coupling at zero bias voltage. (b) Spin transfer torque. Torque e = eV V b = 0.1 V e = eV V b = 0.1 V Parameters A. Manchon et al J. Phys.: Cond. Mat. 19 (2007) A.Manchon et al J. Phys.: Cond. Mat. 20 (2008)

Spin Torque Problem +

Applications Dramatic increase in areal storage density over the past 50 years

Applications GMR spin-valve heads from 1998 to 2004 Benefit of GMR in magnetic recording

Applications Magnetic Tunnel Junctions (MTJ): a reliable path for CMOS/magnetic integration Resistance of MTJ compatible with resistance of passing FET (few k Ω ) MTJ can be deposited in magnetic back end process No CMOS contamination MTJ used as variable resistance controlled by field or current/voltage (Spin-transfer) Commercial CMOS/MTJ products available from EVERSPIN since 2006 (4Mbit MRAM) implemented in Airbus flight controller

Applications Magnetization switching induced by a polarized current Co/Fe/Cu Cu I+I+ I-I- By spin transfer, a spin- polarized current can be used to manipulate the magnetization of magnetic nanostructures instead of by magnetic field. Field scan Current scan Can be used as a new write scheme in MRAM or to generate steady state oscillations leading to RF oscillators J. C. Katine et al Phys.Rev. Lett. 84, 3149 (2000)

Applications Spintronic components Magnetic field sensors Memories RF components

Applications Field induced magnetic switching (FIMS) MRAM “1” “0” Bit states Writing Reading Store data by the direction (parallel or antiparallel) of magnetic layers in MTJ

Applications Thermally Assisted switching (TAS) In MTJ for MRAM, heating produced by Joule dissipation around the tunnel barrier Write temperature ~250°C Use temperature-dependence of switching ability: Write at elevated temperature Store / read at room temperature Use temperature-dependence of switching ability: Write at elevated temperature Store / read at room temperature

Applications RF components based on spin transfer D. Houssameddine et al Nature Materials 6, (2007) RF oscillator with perpendicular to plane polarizer Injection of electrons with out-of-plane spins Steady precession of the magnetization of the soft layer adjacent to the tunnel barrier. Precession (2GHz-40GHz) + Tunnel MR ⇒ RF voltage Interesting for frequency tunable RF oscillators ⇒ Radio opportunism K. J. Lee et al Appl. Phys. Lett. 86, (2005)

Spin Hall Spin Hall effect Current Magnetization

Spin Hall Spin Hall (diffusion model) Charge current Spin current System of equations

Spin Hall Spin Hall in Pt/Py bylayer of size 1000 nm Schematic of Pt/Py bylayer. Sizes are in “nm”. 1 – Pt layer, 2 – Py layer, 3 – Cu electrodes. Current is along x axe. Magnetisation of Py is in xy plane at p /4 angle to x axe. Effective felds induced by Pt SHE in Py near the interface. Adopted values of the parameters: s Pt = ( W nm) -1, L sf Pt = 10 nm, s SH Pt = 0.1 s Pt, s Py = ( W nm)-1, l sf Py = 6 nm, b = 0.7, L J = 1 nm, current density j = 10 7 A/cm 2

Spin Hall Spin Hall in Pt/Py bylayer of size 20 nm Schematic of Pt/Py bylayer. Sizes are in “nm”. 1 – Pt layer, 2 – Py layer, 3 – Cu electrodes. Current is along x axe. Magnetisation of Py is in xy plane at p /4 angle to x axe or along z axe. Effective felds in Co/Pt structure for the direction of magnetization parallel and antiparallel to y axe. Only H y component survive. Values of the parameters: s Co = ( W nm) -1, L sf Co = 10 nm

Spin Hall Spin Hall in Pt/Py bylayer of size 20 nm Effective torques for the case of U M = (cos p /4; sin p /4; 0) near the interface. Averaged values over volume of Co are: = 15 Oe, = -15 Oe, = 3 Oe Effective torques near the interface in case of M || Oz. Averaged values over volume of Co are: = -4 Oe, = - 30 Oe

Conclusions 1.The mechanisms responsible for GMR, TMR and STT are well established 2.The mechanisms limiting the value of GMR and TMR, especially for half-metallic ferromagnets (CrO2, Hauler alloys NiMgSb) has to be clarified 3.The theory describing the diffusive and ballistic spin spin transport on the same footing is still absent 4.Hybrid ferromagnetic/SHE structures may be effective tools for manipulation with magnetic configuration 5.MRAM and other magnetic devices may compete with CMOS in microelectronics