Transcript Slide 1
Thermally-Assisted Magnetization Reversal of a Nanomagnet with Spin-Transfer Torque
D. B. Gopman*1, D. Bedau,1 S. Park2, D. Ravelosona2, E. E. Fullerton3, J. A. Katine4, S. Mangin5 & A. D. Kent1
1Department
of Physics, New York University, New York, New York 10003, USA
2Institut d’Electronique Fondamentale, UMR CNRS 8622, UPS, 91405 Orsay, France
3 CMRR, University of California, San Diego, La Jolla, California 92093-0401, USA
4 San Jose Research Center, Hitachi-GST, San Jose, California 95135, USA
5Institut Jean Lamour, UMR CNRS 7198, Nancy Université, UPV Metz, 54506 Vandoeuvre, France
*Presenting Author e-mail: [email protected]
MOTIVATION
•Nanoscale ferromagnets (FMs): Strong candidate for new
devices based on spin transport—spintronic devices
•Can reverse magnetization by applying a spin current
• Switch high anisotropy FMs (U>40 kBT, T=300 K)
• Low energy consumption
•Applied dc spin currents also reduce the field required to
reverse the magnetization
•How does a dc spin current alter magnetization reversal?
SPIN-VALVE NANOPILLAR
STATISTICAL MEASUREMENTS, IDC ≠ 0
•We can further study
switching out of the P state
as a function of dc current
•Two thin film FMs with perpendicular magnetic anisotropy
•Both Co/Ni Superlattices
•Reference layer magnetically “harder”
•300 nm x 50 nm lithographically patterned elliptical pillar
With extended electrodes for I-V measurements
•Magnetoresistance ratio: (RAP-RP)/RP = 0.4 %
INTRODUCTION
•SPIN VALVE: Nanostructured circuit with two series FM
layers
STATIC I-V MEASUREMENTS
Current-Induced Reversal
Field-Induced Reversal
•GIANT MAGNETORESISTANCE (GMR)
• Change in resistance with H
• Easy Readout of Magnetization
• RAP >> RP
•SPIN-TRANSFER TORQUE
• Transfers spin-angular momentum from
conduction electrons to magnetization
• Destabilize/Switch Magnetization
THEORY
•Within our statistical accuracy (10,000 runs), data fits
equilibrium model
ENERGY BARRIER DEPENDENCE ON IDC
Best-fit parameter E0 for each dataset allows us to
determine barrier height dependence on dc current
STATISTICAL MEASUREMENTS - IDC = 0
P->AP Switching
μ0Hc0 = 175.4 mT
Γ0 = 1 GHz
v = 100 mT/s
E0 = 174.6 kBT
•Magnetization Dynamics
CDF
•Neel-Brown Thermal Activation
•Probability not to switch (H); IDC= 0
•Can we continue to describe the switching field
distributions in the presence of spin-transfer torque
within this equilibrium model of thermal activation?
•Sweep H at fixed rate; measure Hswitch for each trial
•Hswitch defined by sharp drop (rise) in GMR signal
•Generate Switching histograms for ~ 10,000 magnetic field sweeps
•Data is clearly NOT symmetrically distributed
•Plot cumulative density on a Gaussian Quantile Scale for visual enhancement
•Data (blue dots) fits equilibrium statistical model (red line) of thermal activation
•Best-fit curve yields information about the energy barrier, E0, and the coercive field, Hc0
CONCLUSION
•Magnetization reversal in Co-Ni Spin-Valves
•IDC=0 -> Agrees with equilibrium model
•IDC ≠ 0 -> Also agrees with a modified energy
barrier dependent upon IDC
•Barrier height varies monotonically with applied dc
current due to influence of spin-transfer torque