Author:
Dietze S. H.,Shpyrko O. G.
Abstract
The next generation of X-ray sources will feature highly brilliant X-ray beams that will enable the imaging of local nanoscale structures with unprecedented resolution. A general formalism to predict the achievable spatial resolution in coherent diffractive imaging, based solely on diffracted intensities, is provided. The coherent dose necessary to reach atomic resolution depends significantly on the atomic scale structure, where disordered or amorphous materials require roughly three orders of magnitude lower dose compared with the expected scaling of uniform density materials. Additionally, dose reduction for crystalline materials are predicted at certain resolutions based only on their unit-cell dimensions and structure factors.
Publisher
International Union of Crystallography (IUCr)
Subject
Instrumentation,Nuclear and High Energy Physics,Radiation
Cited by
19 articles.
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1. Atomic resolution coherent x-ray imaging with physics-based phase retrieval;npj Computational Materials;2024-08-02
2. Extending Bragg Coherent Diffraction Imaging to the Atomic Scale with Physics-Based Optimization;Optica Imaging Congress 2024 (3D, AOMS, COSI, ISA, pcAOP);2024
3. Extending Bragg Coherent Diffraction Imaging to the Atomic Scale with Physics-Based Optimization;Optica Imaging Congress 2024 (3D, AOMS, COSI, ISA, pcAOP);2024
4. Extending Bragg Coherent Diffraction Imaging to the Atomic Scale with Physics-Based Optimization;Optica Imaging Congress 2024 (3D, AOMS, COSI, ISA, pcAOP);2024
5. Extending Bragg Coherent Diffraction Imaging to the Atomic Scale with Physics-Based Optimization;Optica Imaging Congress 2024 (3D, AOMS, COSI, ISA, pcAOP);2024