Ivana Djuric, Chris P. Search
Published 2006-11-10, updated 2006-11-21Version 3
We examine the spin current generated by quantum dots embedded in an optical microcavity. The dots are connected to leads, which allow electrons to tunnel into and out of the dot. The spin current is generated by spin flip transitions induced by a quantized electromagnetic field inside the cavity with one of the Zeeman states lying below the Fermi level of the leads and the other above. In the limit of strong Coulomb blockade, this model is analogous to the Jaynes-Cummings model in quantum optics. We find that the cavity field amplitude and the spin current exhibit bistability as a function of the laser amplitude, which is driving the cavity mode. Even in the limit of a single dot, the spin current and the Q distribution of the cavity field have a bimodal structure.
Comments: New version includes revised figures and discussion of results
The Interplay of Charge and Spin in Quantum Dots: The Ising Case
Dynamics of the excitations of a quantum dot in a microcavity
Multiplets in Emission of Large Quantum Dots in Microcavities
