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2 results

  • 4 - Spatial Coherent and Incoherent Optical Systems

  • Yaping Zhang, Kunming University of Science and Technology, China, Ting-Chung Poon, Virginia Polytechnic Institute and State University
  • Book:
    Modern Information Optics with MATLAB
    Published online:
    22 December 2022
    Print publication:
    05 January 2023, pp 119-150

  • Summary

    To have some basic understanding of optical coherence, we discuss temporal coherence and spatial coherence quantitatively in the beginning of the Chapter. We then concentrate on spatial coherent image processing, followed by spatially incoherent image processing. While spatial coherent imaging systems lead to the concept of coherent point spread function and coherent transfer function, spatially incoherent imaging system introduces intensity point spread function and optical transfer function. Scanning image processing is also covered in the chapter, illustrating an important aspect in that a mask in front of the photodetector can change the coherence properties of the optical system. Finally, two-pupil synthesis of optical transfer functions is discussed, illustrating bipolar processing in incoherent imaging systems.

  • Modulating Electron Beam–Sample Interactions in Imaging and Diffraction Modes by Dose Fractionation with Low Dose Rates

  • Christian Kisielowski, Petra Specht, Steven J. Rozeveld, Joo Kang, Alyssa J. Fielitz, David Barton, Anthony C. Salazar, Oscar D. Dubon, Dirk Van Dyck, David F. Yancey
  • Journal:
    Microscopy and Microanalysis / Volume 27 / Issue 6 / December 2021
    Published online by Cambridge University Press:
    21 September 2021, pp. 1420-1430
    Print publication:
    December 2021
    • Article
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  • Technological opportunities are explored to enhance detection schemes in transmission electron microscopy (TEM) that build on the detection of single-electron scattering events across the typical spectrum of interdisciplinary applications. They range from imaging with high spatiotemporal resolution to diffraction experiments at the window to quantum mechanics, where the wave-particle dualism of single electrons is evident. At the ultimate detection limit, where isolated electrons are delivered to interact with solids, we find that the beam current dominates damage processes instead of the deposited electron charge, which can be exploited to modify electron beam-induced sample alterations. The results are explained by assuming that all electron scattering are inelastic and include phonon excitation that can hardly be distinguished from elastic electron scattering. Consequently, a coherence length and a related coherence time exist that reflect the interaction of the electron with the sample and change linearly with energy loss. Phonon excitations are of small energy (<100 meV), but they occur frequently and scale with beam current in the irradiated area, which is why we can detect their contribution to beam-induced sample alterations and damage.