Course 4 Quantum optical implementation of quantum information processing

Optical isolation is important for protecting a laser from damage due to the detrimental back reflection of light. It typically relies on breaking Lorentz reciprocity and normally is achieved via the Faraday magneto-optical effect, requiring a strong external magnetic field. Single-photon isolation, the quantum counterpart of optical isolation, is the key functional component in quantum information processing, but its realization is challenging. In this chapter, we present all-optical schemes for isolating the backscattering from single photons. In the first scheme, we show the single-photon isolation can be realized by using a chiral quantum optical system, in which a quantum emitter asymmetrically couples to nanowaveguide modes or whispering-gallery modes with high optical chirality. Secondly, we propose a chiral optical Kerr nonlinearity to bypass the so-called dynamical reciprocity in nonlinear optics and then achieve room-temperature photon isolation with low insertion loss. The concepts we present may pave the way for quantum information processing in an unconventional way.

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Back to basics: Time-tagging single photons

Photoniques ◽

10.1051/photon/2019s454 ◽

2019 ◽

pp. 54-60

Author(s):

Olivier Alibart ◽

Virginia D’Auria ◽

Grégory Sauder ◽

Laurent Labonte ◽

Sébastien Tanzilli

Keyword(s):

Information Processing ◽

Quantum Information ◽

Quantum Information Processing ◽

Single Photons ◽

Noisy Signal ◽

Special Issue ◽

Optical Fields ◽

Time Correlations ◽

Correlation Measures ◽

Quantum Optical

The analysis of time correlations between photons is the essence of quantum information processing protocols (communication, metrology and computing) presented in this special issue. These correlation measures are derived from fundamental quantum optical techniques formalised by R. Glauber in 1963 [Phys. Rev. 130, 2529] which enable the properties of electromagnetic fields to be measured, i.e. their fluctuations and signatures to be detected in a noisy signal. More generally, those fluctuations are the result of high order interferences and are, in certain cases, directly linked to the "traditional" coherence of the optical fields.

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Quantum optical systems for the implementation of quantum information processing

Reports on Progress in Physics ◽

10.1088/0034-4885/69/4/r01 ◽

2006 ◽

Vol 69 (4) ◽

pp. 853-898 ◽

Cited By ~ 31

Author(s):

T C Ralph

Keyword(s):

Information Processing ◽

Quantum Information ◽

Quantum Information Processing ◽

Optical Systems ◽

Quantum Optical

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CONSTRUCTING 2D AND 3D CLUSTER STATES WITH PHOTONIC MODULES

International Journal of Quantum Information ◽

10.1142/s0219749910006265 ◽

2010 ◽

Vol 08 (01n02) ◽

pp. 149-159 ◽

Cited By ~ 3

Author(s):

RADU IONICIOIU ◽

WILLIAM J. MUNRO

Keyword(s):

Information Processing ◽

Quantum Information ◽

Quantum Computation ◽

Large Scale ◽

Quantum Information Processing ◽

Quantum Repeater ◽

Cluster States ◽

Optical Processor ◽

Quantum Optical ◽

2D And 3D

Large-scale quantum information processing and distributed quantum computation require the ability to perform entangling operations on a large number of qubits. We describe a new photonic module which prepares, deterministically, photonic cluster states using an atom in a cavity as an ancilla. Based on this module, we design a network for constructing 2D cluster states and then we extend the architecture to 3D topological cluster states. Advantages of our design include a passive switching mechanism and the possibility of using global control pulses for the atoms in the cavity. The architecture described here is well-suited for integrated photonic circuits on a chip and could be used as a basis of a future quantum optical processor or in a quantum repeater node.

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