Theoretical analysis of quantum ghost imaging through turbulence

Chan, Kam Wai Clifford; Simon, D. S.; Sergienko, A. V.; Hardy, Nicholas David; Shapiro, Jeffrey H.; Ben Dixon, P.; Dixon, P. Ben; Howland, Gregory A.; Howell, John C.; Eberly, Joseph H.; O'Sullivan, Malcolm N.; Rodenburg, Brandon; Boyd, Robert W.

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American Physical Society, Physical Review A, 4(84), 2011

DOI: 10.1103/physreva.84.043807

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Theoretical analysis of quantum ghost imaging through turbulence

Journal article published in 2011 by Kam Wai Clifford Chan, D. S. Simon, A. V. Sergienko, Nicholas David Hardy, Jeffrey H. Shapiro, P. Ben Dixon, P. Ben Dixon

, Gregory A. Howland, John C. Howell, Joseph H. Eberly, Malcolm N. O'Sullivan, Brandon Rodenburg, Robert W. Boyd

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Abstract

Atmospheric turbulence generally affects the resolution and visibility of an image in long-distance imaging. In a recent quantum ghost imaging experiment [P. B. Dixon et al., Phys. Rev. A 83, 051803 (2011)], it was found that the effect of the turbulence can nevertheless be mitigated under certain conditions. This paper gives a detailed theoretical analysis to the setup and results reported in the experiment. Entangled photons with a finite correlation area and a turbulence model beyond the phase screen approximation are considered.

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Theoretical analysis of quantum ghost imaging through turbulence

Abstract