hide
Free keywords:
CONTINUOUS-VARIABLE SYSTEMS; ERROR-CORRECTION; LINEAR OPTICS;
ENTANGLEMENT DISTILLATION; EXPERIMENTAL REALIZATION; SEPARABILITY
CRITERION; ATOMIC ENSEMBLES; COHERENT STATES; NOISY CHANNELS; TRAPPED
IONSOptics; Physics; Quantum computation; quantum communication; quantum optics;
entanglement; qubits; qumodes; hybrid;
Abstract:
This article reviews recent hybrid approaches to optical quantum information processing, in which both discrete and continuous degrees of freedom are exploited. There are well-known limitations to optical single-photon-based qubit and multi-photon-based qumode implementations of quantum communication and quantum computation, when the toolbox is restricted to the most practical set of linear operations and resources such as linear optics and Gaussian operations and states. The recent hybrid approaches aim at pushing the feasibility, the efficiencies, and the fidelities of the linear schemes to the limits, potentially adding weak or measurement-induced nonlinearities to the toolbox.