Resolution-enhanced quantum imaging by centroid estimation of biphotons

Ermes Toninelli; Paul Antoine Moreau; Thomas Gregory; Adam Mihalyi; Matthew Edgar; Neal Radwell; Miles Padgett

doi:10.1364/OPTICA.6.000347

Resolution-enhanced quantum imaging by centroid estimation of biphotons

Ermes Toninelli, Paul Antoine Moreau, Thomas Gregory, Adam Mihalyi, Matthew Edgar, Neal Radwell, Miles Padgett

Department of Physics

Research output: Contribution to journal › Article › peer-review

59 Citations (Scopus)

Abstract

The spatial resolution of an optical system is limited by diffraction. Various schemes have been proposed to achieve resolution enhancement by employing either a scanning source/detector configuration or a two-photon response of the object. Here, we experimentally demonstrate a full-field resolution-enhancing scheme, based on the centroid estimation of spatially quantum-correlated biphotons. Our standard-quantum-limited scheme is able to image a general non-fluorescing object, using low-energy and low-intensity infrared illumination (i.e., with <0.001 photon per pixel per frame at 710 nm), achieving 41% of the theoretically available resolution enhancement. Images of real-world objects are shown for visual comparison, in which the classically bound resolution is surpassed using our technically straightforward quantum-imaging scheme.

Original language	English
Article number	358182
Pages (from-to)	347-353
Number of pages	7
Journal	Optica
Volume	6
Issue number	3
DOIs	https://doi.org/10.1364/OPTICA.6.000347
Publication status	Published - 2019 Mar 20

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics

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Cite this

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abstract = "The spatial resolution of an optical system is limited by diffraction. Various schemes have been proposed to achieve resolution enhancement by employing either a scanning source/detector configuration or a two-photon response of the object. Here, we experimentally demonstrate a full-field resolution-enhancing scheme, based on the centroid estimation of spatially quantum-correlated biphotons. Our standard-quantum-limited scheme is able to image a general non-fluorescing object, using low-energy and low-intensity infrared illumination (i.e., with <0.001 photon per pixel per frame at 710 nm), achieving 41% of the theoretically available resolution enhancement. Images of real-world objects are shown for visual comparison, in which the classically bound resolution is surpassed using our technically straightforward quantum-imaging scheme.",

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AU - Radwell, Neal

AU - Padgett, Miles

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AB - The spatial resolution of an optical system is limited by diffraction. Various schemes have been proposed to achieve resolution enhancement by employing either a scanning source/detector configuration or a two-photon response of the object. Here, we experimentally demonstrate a full-field resolution-enhancing scheme, based on the centroid estimation of spatially quantum-correlated biphotons. Our standard-quantum-limited scheme is able to image a general non-fluorescing object, using low-energy and low-intensity infrared illumination (i.e., with <0.001 photon per pixel per frame at 710 nm), achieving 41% of the theoretically available resolution enhancement. Images of real-world objects are shown for visual comparison, in which the classically bound resolution is surpassed using our technically straightforward quantum-imaging scheme.

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Resolution-enhanced quantum imaging by centroid estimation of biphotons

Abstract

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