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Browse Journals & Magazines > Applied Physics Letters ...> Volume:97 Issue:25 Help

Real-time single-shot three-dimensional and contrast-enhanced optical coherence imaging using phase coherent photorefractive quantum wells

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4 Author(s)
Kabir, A. ; Department of Physics, University of Cincinnati, Cincinnati, Ohio 45221-0011, USA ; Dongol, A. ; Wang, X. ; Wagner, H.P.

Your organization might have access to this article on the publisher's site. To check, click on this link:http://dx.doi.org/+10.1063/1.3531589 

We demonstrate two real-time optical coherence imaging acquisition modes using all-optical phase coherent photorefractive ZnSe quantum wells as dynamic holographic films. These films use the coherence of excitons for time-gating which provides depth information of an object according to the brightness profile of its holographic image. This quality allows depth-resolved imaging of moving particles with a resolution of a few micrometers in a single-shot three-dimensional mode. In a complementary contrast-enhanced mode moving particles are imaged by the local enhancement of a static reference hologram, enabling optical coherence imaging at a large depth-of-field.

Published in:
Applied Physics Letters  (Volume:97 ,  Issue: 25 )

Date of Publication: Dec 2010

Page(s):
251116 - 251116-3
ISSN :
0003-6951
Digital Object Identifier :
10.1063/1.3531589
Product Type:
Journals & Magazines
Date of Current Version :
30 December 2010
Issue Date :
Dec 2010

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