Nonequilibrium spin-polarized transport through two parallel-coupled quantum dots

Spin-polarized transport through an Aharonov-Bohm ring containing two quantum dots (QDs) in each of its arms is studied by using the nonequilibrium Green's function technique. We take both the Rashba spin-orbit interaction that exists in one of the QDs, and an inhomogeneous magnetic flux penetrating through the ring, into consideration. It is found that a 100% spin-polarized current can be driven out of the QDs ring, and both the spin directions and the magnitude of the outgoing current can be controlled. The origin of the pure spin-up or spin-down current is interpreted in terms of the spin accumulation in the QDs. This device is realizable by presently available technologies and can be used as a spin filter.