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Time‐of‐flight modulated intensity small‐angle neutron scattering measurement of the self‐diffusion constant of water
Author(s) -
Kuhn Stephen J.,
Geerits Niels,
Franz Christian,
Plomp Jeroen,
Dalgliesh Robert M.,
Parnell Steven R.
Publication year - 2021
Publication title -
journal of applied crystallography
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.429
H-Index - 162
ISSN - 1600-5767
DOI - 10.1107/s1600576721002612
Subject(s) - neutron spin echo , neutron scattering , small angle neutron scattering , diffusion , scattering , neutron , optics , fick's laws of diffusion , range (aeronautics) , time of flight , nuclear magnetic resonance , spin echo , intensity (physics) , computational physics , materials science , physics , nuclear physics , magnetic resonance imaging , medicine , radiology , composite material , thermodynamics
The modulated intensity by zero effort small‐angle neutron scattering (MI‐SANS) technique is used to measure scattering with a high energy resolution on samples normally ill‐suited for neutron resonance spin echo. The self‐diffusion constant of water is measured over a q – t range of 0.01–0.2 Å −1 and 70–500 ps. In addition to demonstrating the methodology of using time‐of‐flight MI‐SANS instruments to observe diffusion in liquids, the results support previous measurements on water performed with different methods. This polarized neutron technique simultaneously measures the intermediate scattering function for a wide range of time and length scales. Two radio frequency flippers were used in a spin‐echo setup with a 100 kHz frequency difference in order to create a high‐resolution time measurement. The results are compared with self‐diffusion measurements made by other techniques and the general applicability of MI‐SANS at a pulsed source is assessed.