Quantum information processing using frequency control of impurity spins in diamond
Abstract
Spin degrees of freedom of charged nitrogen-vacancy (NV-) centers in diamond have large decoherence times even at room temperature, can be initialized and read out using optical fields, and are therefore a promising candidate for solid state qubits. Recently, quantum manipulations of NV-- centers using RF fields were experimentally realized. In this paper we show; first, that such operations can be controlled by varying the frequency of the signal, instead of its amplitude, and NV-- centers can be selectively addressed even with spacially uniform RF signals; second, that when several - centers are placed in an off-resonance optical cavity, a similar application of classical optical fields provides a controlled coupling and enables a universal two-qubit gate (CPHASE). RF and optical control together promise a scalable quantum computing architecture.
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