Quantum and optical technology

On quantum efficiencies of optical states

Optica Publishing Group (2011) qtuh4

Authors:

DW Berry, AI Lvovsky

Linear-optical processing cannot increase photon efficiency.

Physical review letters 105:20 (2010) 203601

Authors:

DW Berry, AI Lvovsky

Abstract:

We answer the question whether linear-optical processing of the states produced by one or multiple imperfect single-photon sources can improve the single-photon fidelity. This processing can include arbitrary interferometers, coherent states, feedforward, and conditioning on results of detections. We show that without introducing multiphoton components, the single-photon fraction in any of the single-mode states resulting from such processing cannot be made to exceed the efficiency of the best available photon source. If multiphoton components are allowed, the single-photon fidelity cannot be increased beyond 1/2. We propose a natural general definition of the quantum-optical state efficiency, and show that it cannot increase under linear-optical processing.

Preservation of loss in linear-optical processing

(2010)

Authors:

Dominic W Berry, AI Lvovsky

Quantum process tomography with coherent states

(2010)

Authors:

Saleh Rahimi-Keshari, Artur Scherer, Ady Mann, Ali T Rezakhani, AI Lvovsky, Barry C Sanders

A bridge between the single-photon and squeezed-vacuum states.

Optics express 18:17 (2010) 18254-18259

Authors:

Nitin Jain, SR Huisman, Erwan Bimbard, AI Lvovsky

Abstract:

The two modes of the Einstein-Podolsky-Rosen quadrature entangled state generated by parametric down-conversion interfere on a beam splitter of variable splitting ratio. Detection of a photon in one of the beam splitter output channels heralds preparation of a signal state in the other, which is characterized using homodyne tomography. By controlling the beam splitting ratio, the signal state can be chosen anywhere between the single-photon and squeezed state.