Reconstructing state mixtures from diffraction measurements
Reconstructing state mixtures from diffraction measurements
Progress in imaging and metrology depends on exquisite control over and comprehensive characterization of wave fields. As reflected in its name, coherent diffractive imaging relies on high coherence when reconstructing highly resolved images from diffraction intensities alone without the need for image-forming lenses. Fully coherent light can be described adequately by a single pure state. Yet partial coherence and imperfect detection often need to be accounted for, requiring statistical optics or the superposition of states. Furthermore, the dynamics of samples are increasingly the very objectives of experiments. Here we provide a general analytic approach to the characterization of diffractive imaging systems that can be described as low-rank mixed states. We use experimental data and simulations to show how the reconstruction technique compensates for and characterizes various sources of decoherence quantitatively. Based on ptychography, the procedure is closely related to quantum state tomography and is equally applicable to high-resolution microscopy, wave sensing and fluctuation measurements. As a result, some of the most stringent experimental conditions in ptychography can be relaxed, and susceptibility to imaging artefacts is reduced. Furthermore, the method yields high-resolution images of mixed states within the sample, which may include quantum mixtures or fast stationary stochastic processes such as vibrations, switching or steady flows.
68-71
Thibault, Pierre
975a4c7b-6ca9-4958-b362-9eba10ab926b
Menzel, Andreas
82ceca70-40ae-40f2-81c4-07c3f485bc15
7 February 2013
Thibault, Pierre
975a4c7b-6ca9-4958-b362-9eba10ab926b
Menzel, Andreas
82ceca70-40ae-40f2-81c4-07c3f485bc15
Thibault, Pierre and Menzel, Andreas
(2013)
Reconstructing state mixtures from diffraction measurements.
Nature, 494 (7435), .
(doi:10.1038/nature11806).
Abstract
Progress in imaging and metrology depends on exquisite control over and comprehensive characterization of wave fields. As reflected in its name, coherent diffractive imaging relies on high coherence when reconstructing highly resolved images from diffraction intensities alone without the need for image-forming lenses. Fully coherent light can be described adequately by a single pure state. Yet partial coherence and imperfect detection often need to be accounted for, requiring statistical optics or the superposition of states. Furthermore, the dynamics of samples are increasingly the very objectives of experiments. Here we provide a general analytic approach to the characterization of diffractive imaging systems that can be described as low-rank mixed states. We use experimental data and simulations to show how the reconstruction technique compensates for and characterizes various sources of decoherence quantitatively. Based on ptychography, the procedure is closely related to quantum state tomography and is equally applicable to high-resolution microscopy, wave sensing and fluctuation measurements. As a result, some of the most stringent experimental conditions in ptychography can be relaxed, and susceptibility to imaging artefacts is reduced. Furthermore, the method yields high-resolution images of mixed states within the sample, which may include quantum mixtures or fast stationary stochastic processes such as vibrations, switching or steady flows.
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Accepted/In Press date: 16 November 2012
Published date: 7 February 2013
Identifiers
Local EPrints ID: 431000
URI: http://eprints.soton.ac.uk/id/eprint/431000
ISSN: 0028-0836
PURE UUID: 4714a000-8fd7-45b7-85a6-57187f2c88cf
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Date deposited: 21 May 2019 16:30
Last modified: 16 Mar 2024 01:51
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Author:
Pierre Thibault
Author:
Andreas Menzel
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