Ian Walmsley

Direct observation of sub-binomial light

Institute of Electrical and Electronics Engineers (IEEE) (2013) 1-1

Authors:

Tim J Bartley, Gaia Donati, Xian-Min Jin, Animesh Datta, Marco Barbieri, Ian A Walmsley

High-efficiency Bragg Grating Enhanced On-chip Photon-number-resolving Detectors

Institute of Electrical and Electronics Engineers (IEEE) (2013) 1-1

Authors:

PL Mennea, B Calkins, BJ Metcalf, T Gerrits, AE Lita, JC Gates, WS Kolthammer, JB Spring, PC Humphrles, NA Tomlin, AE Fox, A Lamas Linares, RP Mirin, SW Nam, IA Walmsley, PGR Smith

Measuring nonlocal coherence with weak-field homodyne detection

Institute of Electrical and Electronics Engineers (IEEE) (2013) 1-1

Authors:

Tim J Bartley, Gaia Donati, Xian-Min Jin, Animesh Datta, Marco Barbieri, Ian A Walmsley

Direct observation of sub-binomial light

Physical Review Letters 110:17 (2013)

Authors:

TJ Bartley, G Donati, XM Jin, A Datta, M Barbieri, IA Walmsley

Abstract:

Nonclassical states of light are necessary resources for quantum technologies such as cryptography, computation and the definition of metrological standards. Observing signatures of nonclassicality generally requires inferring either the photon number distribution or a quasiprobability distribution indirectly from a set of measurements. Here, we report an experiment in which the nonclassical character of families of quantum states is assessed by direct inspection of the outcomes from a multiplexed photon counter. This scheme does not register the actual photon number distribution; the statistics of the detector clicks alone serve as a witness of nonclassicality, as proposed by Sperling et al.. Our work paves a way for the practical characterization of increasingly sophisticated states and detectors. © 2013 American Physical Society.

Enhancing multiphoton rates with quantum memories

Physical Review Letters 110:13 (2013)

Authors:

J Nunn, NK Langford, WS Kolthammer, TFM Champion, MR Sprague, PS Michelberger, XM Jin, DG England, IA Walmsley

Abstract:

Single photons are a vital resource for optical quantum information processing. Efficient and deterministic single photon sources do not yet exist, however. To date, experimental demonstrations of quantum processing primitives have been implemented using nondeterministic sources combined with heralding and/or postselection. Unfortunately, even for eight photons, the data rates are already so low as to make most experiments impracticable. It is well known that quantum memories, capable of storing photons until they are needed, are a potential solution to this "scaling catastrophe." Here, we analyze in detail the benefits of quantum memories for producing multiphoton states, showing how the production rates can be enhanced by many orders of magnitude. We identify the quantity ηB as the most important figure of merit in this connection, where η and B are the efficiency and time-bandwidth product of the memories, respectively. © 2013 American Physical Society.