Ultrafast initialization and QND-readout of a spin qubit via control of nanodot-vacuum coupling
arXiv:cond-mat/0408148 · doi:10.1103/PhysRevB.72.081306
Abstract
Ultrafast initialization enables fault-tolerant processing of quantum information while QND readout enables scalable quantum computation. By spatially assembling photon resonators and wave-guides around an n-doped nanodot and by temporally designing optical pump pulses, an efficient quantum pathway can be established from an electron spin to a charged exciton to a cavity photon and finally to a flying photon in the waveguide. Such control of vacuum-nanodot coupling can be exploited for ultrafast initialization and QND readout of the spin, which are particularly compatible with the optically driven spin quantum computers.
4 pages 3 figures