Continuous-wave spatial quantum correlations of light induced by multiple scattering

Publication: Research - peer-reviewJournal article – Annual report year: 2012

Standard

Harvard

APA

CBE

MLA

Vancouver

Author

Bibtex

@article{adbc9bbd089f406facadb6967dca348b,
title = "Continuous-wave spatial quantum correlations of light induced by multiple scattering",
publisher = "American Physical Society",
author = "Stephan Smolka and Ott, {Johan Raunkjær} and Alexander Huck and Andersen, {Ulrik Lund} and Peter Lodahl",
note = "©2012 American Physical Society",
year = "2012",
doi = "10.1103/PhysRevA.86.033814",
volume = "86",
number = "3",
pages = "033814",
journal = "Physical Review A (Atomic, Molecular and Optical Physics)",
issn = "1050-2947",

}

RIS

TY - JOUR

T1 - Continuous-wave spatial quantum correlations of light induced by multiple scattering

A1 - Smolka,Stephan

A1 - Ott,Johan Raunkjær

A1 - Huck,Alexander

A1 - Andersen,Ulrik Lund

A1 - Lodahl,Peter

AU - Smolka,Stephan

AU - Ott,Johan Raunkjær

AU - Huck,Alexander

AU - Andersen,Ulrik Lund

AU - Lodahl,Peter

PB - American Physical Society

PY - 2012

Y1 - 2012

N2 - We present theoretical and experimental results on spatial quantum correlations induced by multiple scattering of nonclassical light. A continuous-mode quantum theory is derived that enables determining the spatial quantum correlation function from the fluctuations of the total transmittance and reflectance. Utilizing frequency-resolved quantum noise measurements, we observe that the strength of the spatial quantum correlation function can be controlled by changing the quantum state of an incident bright squeezed-light source. Our results are found to be in excellent agreement with the developed theory and form a basis for future research on, e. g., quantum interference of multiple quantum states in a multiple scattering medium.

AB - We present theoretical and experimental results on spatial quantum correlations induced by multiple scattering of nonclassical light. A continuous-mode quantum theory is derived that enables determining the spatial quantum correlation function from the fluctuations of the total transmittance and reflectance. Utilizing frequency-resolved quantum noise measurements, we observe that the strength of the spatial quantum correlation function can be controlled by changing the quantum state of an incident bright squeezed-light source. Our results are found to be in excellent agreement with the developed theory and form a basis for future research on, e. g., quantum interference of multiple quantum states in a multiple scattering medium.

KW - OPTICS

KW - PHYSICS,

KW - TRANSMISSION

KW - MEDIA

KW - REFLECTION

KW - PHASE

KW - NOISE

U2 - 10.1103/PhysRevA.86.033814

DO - 10.1103/PhysRevA.86.033814

JO - Physical Review A (Atomic, Molecular and Optical Physics)

JF - Physical Review A (Atomic, Molecular and Optical Physics)

SN - 1050-2947

IS - 3

VL - 86

SP - 033814

ER -