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Paper detail

Quantum Interferometric Optical Lithography: Exploiting Entanglement to Beat The Diffraction Limit

Classical, interferometric, optical lithography is diffraction limited to writing features of a size lambda/2 or greater, where lambda is the optical wavelength. Using nonclassical photon number states, entangled N at a time, we show that it is possible to write features of minimum size lambda/(2N) in an N-photon absorbing substrate. This result surpasses the usual classical diffraction limit by a factor of N. Since the number of features that can be etched on a two-dimensional surface scales inversely as the square of the feature size, this allows one to write a factor of N^2 more elements on a semiconductor chip. A factor of N = 2 can be achieved easily with entangled photon pairs generated from optical parametric downconversion. It is shown how to write arbitrary 2D patterns by using this method.

preprint2000arXivOpen access
Agedi N. BotoPieter KokDaniel S. AbramsSamuel L. BraunsteinColin P. WilliamsJonathan P. Dowling
quant-ph
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Agedi N. BotoPieter KokDaniel S. AbramsSamuel L. BraunsteinColin P. WilliamsJonathan P. Dowling

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