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Stochastic theory of nonlinear auto-oscillator: Spin-torque nano-oscillator

NLPV, Gallipoli, Italy. June 15, 2008. Stochastic theory of nonlinear auto-oscillator: Spin-torque nano-oscillator. Vasil Tiberkevich Department of Physics, Oakland University, Rochester, MI, USA. In collaboration with: Andrei Slavin (Oakland University, Rochester, MI, USA)

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Stochastic theory of nonlinear auto-oscillator: Spin-torque nano-oscillator

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  1. NLPV, Gallipoli, Italy June 15, 2008 Stochastic theory of nonlinear auto-oscillator:Spin-torque nano-oscillator Vasil Tiberkevich Department of Physics, Oakland University,Rochester, MI, USA • In collaboration with: • Andrei Slavin (Oakland University, Rochester, MI, USA) • Joo-Von Kim (Universite Paris-Sud, Orsay , France)

  2. Outline • Introduction • Linear and nonlinear auto-oscillators • Spin-torque oscillator (STO) • Stochastic model of a nonlinear auto-oscillator • Generation linewidth of a nonlinear auto-oscillator • Theoretical results • Comparison with experiment (STO) • Summary

  3. Outline • Introduction • Linear and nonlinear auto-oscillators • Spin-torque oscillator (STO) • Stochastic model of a nonlinear auto-oscillator • Generation linewidth of a nonlinear auto-oscillator • Theoretical results • Comparison with experiment (STO) • Summary

  4. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle

  5. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model Unperturbed system:

  6. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model Unperturbed system: Perturbed system:

  7. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model Unperturbed system: Perturbed system:

  8. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model

  9. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model • Weakly nonlinear model

  10. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model • Weakly nonlinear model Complex amplitude:

  11. Models of (weakly perturbed) auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model • Weakly nonlinear model

  12. Linear and nonlinear auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model • Weakly nonlinear model

  13. Linear and nonlinear auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model • Weakly nonlinear model Nonlinear auto-oscillator: frequency depends on the amplitude

  14. Linear and nonlinear auto-oscillators Auto-oscillator – autonomous dynamical system with stable limit cycle • Phase model • Weakly nonlinear model All conventional auto-oscillators are linear.

  15. Outline • Introduction • Linear and nonlinear auto-oscillators • Spin-torque oscillator (STO) • Stochastic model of a nonlinear auto-oscillator • Generation linewidth of a nonlinear auto-oscillator • Theoretical results • Comparison with experiment (STO) • Summary

  16. Spin-torque oscillator Electric current I Magnetic metal Ferromagnetic metal – strong self-interaction – strong nonlinearity Electric current – compensation of dissipation – auto-oscillatory dynamics

  17. Spin-torque oscillator Electric current I M(t) p Spin-transfer torque: J. Slonczewski, J. Magn. Magn. Mat. 159, L1 (1996) L. Berger, Phys. Rev. B. 54, 9353 (1996)

  18. Equation for magnetization Landau-Lifshits-Gilbert-Slonczewski equation:

  19. Equation for magnetization precession Landau-Lifshits-Gilbert-Slonczewski equation: – conservative torque (precession)

  20. Equation for magnetization damping precession Landau-Lifshits-Gilbert-Slonczewski equation: – conservative torque (precession) – dissipative torque (positive damping)

  21. Equation for magnetization damping spin torque precession Landau-Lifshits-Gilbert-Slonczewski equation: – conservative torque (precession) – dissipative torque (positive damping) – spin-transfer torque (negative damping)

  22. Equation for magnetization damping spin torque precession Landau-Lifshits-Gilbert-Slonczewski equation: When negative current-induced damping compensates natural magnetic damping, self-sustained precession of magnetization starts.

  23. Experimental studies of spin-torque oscillators Microwave power S.I. Kiselev et al., Nature 425, 380 (2003)

  24. Experimental studies of spin-torque oscillators M.R. Pufall et al., Appl. Phys. Lett. 86, 082506 (2005)

  25. Specific features of spin-torque oscillators S.I. Kiselev et al., Nature 425, 380 (2003) M.R. Pufall et al., Appl. Phys. Lett. 86, 082506 (2005)

  26. Specific features of spin-torque oscillators • Strong influence of thermal noise (spin-torque NANO-oscillator) S.I. Kiselev et al., Nature 425, 380 (2003) M.R. Pufall et al., Appl. Phys. Lett. 86, 082506 (2005)

  27. Specific features of spin-torque oscillators • Strong influence of thermal noise (spin-torque NANO-oscillator) S.I. Kiselev et al., Nature 425, 380 (2003) • Strong frequency nonlinearity M.R. Pufall et al., Appl. Phys. Lett. 86, 082506 (2005)

  28. Outline • Introduction • Linear and nonlinear auto-oscillators • Spin-torque oscillator (STO) • Stochastic model of a nonlinear auto-oscillator • Generation linewidth of a nonlinear auto-oscillator • Theoretical results • Comparison with experiment (STO) • Summary

  29. Nonlinear oscillator model damping spin torque precession – oscillation power – oscillation phase

  30. Nonlinear oscillator model damping spin torque precession precession – oscillation power – oscillation phase

  31. Nonlinear oscillator model damping spin torque precession precession positive damping – oscillation power – oscillation phase

  32. Nonlinear oscillator model damping spin torque precession precession positive damping negative damping – oscillation power – oscillation phase

  33. How to find parameters of the model?

  34. How to find parameters of the model? • Start from the Landau-Lifshits-Gilbert-Slonczewski equation • Rewrite it in canonical coordinates • Perform weakly-nonlinear expansion • Diagonalize linear part of the Hamiltonian • Perform renormalization of non-resonant three-wave processes • Take into account only resonant four-wave processes • Average dissipative terms over “fast” conservative motion • and obtain analytical results for

  35. Deterministic theory Stationary solution: Stationary power is determined from the condition of vanishing total damping: – oscillation power Stationary frequency is determined by the oscillation power:

  36. Deterministic theory: Spin-torque oscillator Stationary power is determined from the condition of vanishing total damping: Stationary frequency is determined by the oscillation power: – supercriticality parameter – threshold current – FMR frequency – nonlinear frequency shift

  37. Generated frequency Frequency as function of applied field Frequency as function of magnetization angle Experiment: W.H. Rippard et al., Phys. Rev. Lett. 92, 027201 (2004) Experiment: W.H. Rippard et al., Phys. Rev. B 70, 100406 (2004)

  38. Stochastic nonlinear oscillator model Stochastic Langevin equation: Random thermal noise: – thermal equilibrium power of oscillations: l– scale factor that relates energy and power:

  39. Fokker-Planck equation for a nonlinear oscillator Probability distribution function (PDF) P(t, p, ) describes probability that oscillator has the power p = |c|2 and the phase  = arg(c) at the moment of time t. Deterministic terms describe noise-free dynamics of the oscillator Stochastic terms describe thermal diffusion in the phase space

  40. Stationary PDF • Stationary probability distribution function P0: • does not depend on the time t (by definition); • does not depend on the phase  (by phase-invariance of FP equation). Ordinary differential equation for P0(p): Stationary PDF for an arbitrary auto-oscillator: Constant Z0 is determined by the normalization condition

  41. Analytical results for STO “Material functions” for the case of STO: Analytical expression for the stationary PDF: Analytical expression for the mean oscillation power Here – exponential integral function

  42. Power in the near-threshold region Experiment: Q. Mistral et al., Appl. Phys. Lett. 88, 192507 (2006). Theory: V. Tiberkevich et al., Appl. Phys. Lett. 91, 192506 (2007).

  43. Outline • Introduction • Linear and nonlinear auto-oscillators • Spin-torque oscillator (STO) • Stochastic model of a nonlinear auto-oscillator • Generation linewidth of a nonlinear auto-oscillator • Theoretical results • Comparison with experiment (STO) • Summary

  44. Linewidth of a conventional oscillator ~ +R0 –Rs L C e(t) Classical result (see, e.g., A. Blaquiere, Nonlinear System Analysis (Acad. Press, N.Y., 1966)): Full linewidth of an electrical oscillator

  45. Linewidth of a conventional oscillator ~ +R0 –Rs L C e(t) Classical result (see, e.g., A. Blaquiere, Nonlinear System Analysis (Acad. Press, N.Y., 1966)): Full linewidth of an electrical oscillator Physical interpretation of the classical result Frequency Equilibrium half-linewidth Oscillation energy

  46. Linewidth of a laser Quantum limit for the linewidth of a single-mode laser (Schawlow-Townes limit) [A.L. Schawlow and C.H. Townes, Phys. Rev. 112, 1940 (1958)]

  47. Linewidth of a laser Quantum limit for the linewidth of a single-mode laser (Schawlow-Townes limit) [A.L. Schawlow and C.H. Townes, Phys. Rev. 112, 1940 (1958)] Physical interpretation of the classical result Effective thermal energy Oscillation energy

  48. Linewidth of a spin-torque oscillator Experiment by W.H. Rippard et al., DARPA Review (2004). Theoretical result [J.-V. Kim, PRB 73, 174412 (2006)]:

  49. Linewidth of a spin-torque oscillator Experiment by W.H. Rippard et al., DARPA Review (2004). Theoretical result [J.-V. Kim, PRB 73, 174412 (2006)]: Physical interpretation:

  50. Linewidth of a spin-torque oscillator Experiment by W.H. Rippard et al., DARPA Review (2004). Theoretical result [J.-V. Kim, PRB 73, 174412 (2006)]: Physical interpretation:

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