Spin-current Kondo effect: Kondo effect in the presence of spin accumulation

We study spin-dependent transport through a quantum dot with Zeeman split levels coupled to ferromagnetic leads and under influence of microwave irradiation. Current polarization, spin current, spin accumulation and tunneling magnetoresistance are analyzed using nonequilibrium Green's function formalism and rate equations. Spin-dependent beats in spin resolved currents are observed. The effects of magnetic field, temperature and Coulomb interaction on these beats are studied.

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Spin current and spin accumulation near a Josephson junction between a singlet and triplet superconductor

Physical Review B ◽

10.1103/physrevb.80.024504 ◽

2009 ◽

Vol 80 (2) ◽

Cited By ~ 41

Author(s):

Chi-Ken Lu ◽

Sungkit Yip

Keyword(s):

Josephson Junction ◽

Spin Current ◽

Spin Accumulation

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Manipulating Spin Current in the Magnetic Nanopillar

Journal of Nanoscience and Nanotechnology ◽

10.1166/jnn.2007.18021 ◽

2007 ◽

Vol 7 (1) ◽

pp. 259-264 ◽

Cited By ~ 2

Author(s):

T. Yang ◽

A. Hirohata ◽

T. Kimura ◽

Y. Otani

Keyword(s):

Layer Thickness ◽

Spin Relaxation ◽

Spin Diffusion ◽

Diffusion Length ◽

Ferromagnetic Layer ◽

Spin Current ◽

Spin Accumulation ◽

Magnetization Switching ◽

Capping Layer ◽

Spin Diffusion Length

Because of the capability to switch the magnetization of a nanoscale magnet, the spin transfer effect is critical for the application of magnetic random access memory. For this purpose, it is important to enhance the spin current carried by the charge current. Calculations based on the diffusive spin-dependent transport equations reveal that the magnitude of spin current can be tuned by modifying the ferromagnetic layer and the spin relaxation process in the device. Increasing the ferromagnetic layer thickness is found to enhance both the spin current and the spin accumulation. On the other hand, a strong spin relaxation in the capping layer also increases the spin current but suppresses the spin accumulation. To demonstrate the theoretical results, nanopillar structures with the size of ∼100 nm are fabricated and the current-induced magnetization switching behaviors are experimentally studied. When the ferromagnetic layer thickness is increased from 3 nm to 20 nm, the critical switching current for the current-induced magnetization switching is significantly reduced, indicating the enhancement of the spin current. When the Au capping layer with a short spin-diffusion length replaces the Cu capping layer with a long spin-diffusion length, the reduction of the critical switching current is also observed.

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Effects of FM/NM Interfaces on Spin Accumulation in Free Layer of Pseudo-Spin-Valve Structure

MRS Proceedings ◽

10.1557/proc-998-j02-03 ◽

2007 ◽

Vol 998 ◽

Author(s):

Jiuning Hu ◽

Min Ren ◽

Lei Zhang ◽

Ning Deng ◽

Hao Dong ◽

...

Keyword(s):

Spin Diffusion ◽

Spin Valve ◽

Spin Current ◽

Spin Accumulation ◽

Free Layer ◽

Fixed Layer ◽

Spacer Layer ◽

Polarization Factor ◽

Valve Structure ◽

Parallel Configuration

ABSTRACTThe ferromagnetic/nonmagnetic (FM/NM) interfacial effects on the spin accumulation in the free layer were studied in a pseudo-spin-valve structure (PSVs) consisting of two FM layers separated by a NM spacer layer. We developed a spin current model for the current-induced magnetic switching (CIMS) effect based on the spin diffusion equations and appropriate boundary conditions, and derived a new formula for the spin-dependent electrochemical potentials that are related to the spin-dependent density of states. The results indicate that the spin accumulation in the free layer mainly depends on the interfacial spin asymmetry coefficient Ξ?which originates from the spin-dependent interfacial conductance. In the parallel (anti-parallel) configuration of the magnetization direction for the free and fixed layer, the positive (negative) electron current (electrons from the free layer to the fixed layer and vice versa) drives the spin current polarization factor at the interface between the top electrode and the free layer to vary from Ξ? (-Ξ?) to 0, while at the interface between the free layer and the spacer layer the spin current polarization factor vary from Ξ? (0) to Ξ?/2, which means the total spin current polarization factor in the free layer varies from 0 (Ξ?) to Ξ?/2. These results show that the anti-parallel configuration has a less critical switching current than that of the parallel configuration. Thus, we can design PSVs with symmetrical critical current based on the model.

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