Complete temporal characterization of a single photon

Precise information about the temporal mode of optical states is crucial for optimizing their interaction efficiency between themselves and/or with matter in various quantum communication devices. Here we propose and experimentally demonstrate a method of determining both the real and imaginary comp...

Full description

Saved in:
Bibliographic Details
Published in:Light, science & applications science & applications, 2015-06, Vol.4 (6), p.e298-e298
Main Authors: Qin, Zhongzhong, Prasad, Adarsh S, Brannan, Travis, MacRae, Andrew, Lezama, A, Lvovsky, AI
Format: Article
Language:English
Subjects:
639/766/400/385
639/766/400/3925
639/766/400/482
Applied and Technical Physics
Atomic
Autocorrelation functions
Classical and Continuum Physics
Density
Four-wave mixing
Lasers
Molecular
Optical and Plasma Physics
Optical Devices
Optics
Optimization
original-article
Oscillators
Photocurrent
Photonics
Photons
Physics
Physics and Astronomy
Test procedures
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Precise information about the temporal mode of optical states is crucial for optimizing their interaction efficiency between themselves and/or with matter in various quantum communication devices. Here we propose and experimentally demonstrate a method of determining both the real and imaginary components of a single photon's temporal density matrix by measuring the autocorrelation function of the photocurrent from a balanced homodyne detector at multiple local oscillator frequencies. We test our method on single photons heralded from biphotons generated via four-wave mixing in an atomic vapor and obtain excellent agreement with theoretical predictions for several settings. Quantum optics: single-photon characterization A convenient scheme for characterizing the temporal properties of a single photon looks set to aid experiments in quantum optics. An international team of scientists from Canada, China, USA, Uruguay and Russia says that this approach can be used to determine the complete mode structure of a photon, in particular, the real and imaginary parts of its temporal density matrix. This information is important for quantum communication experiments for which it is often critical to match photon modes. The characterization scheme, which the researchers term polychromatic optical heterodyne tomography, works by collecting autocorrelation data of homodyne photocurrent at multiple local oscillator frequencies. The team says that tests of the technique with single photons generated by four-wave mixing in an atomic vapour agree well with theoretical predictions.
ISSN:2047-7538
2047-7538
DOI:10.1038/lsa.2015.71