Accurate Background Correction in Neutron Reflectometry Studies of Soft Condensed Matter Films in Contact with Fluid Reservoirs

Overview

Journal J Appl Crystallogr

Date 2021 Jul 1

PMID 34194075

Citations 2

Authors

David P Hoogerheide

Frank Heinrich

Brian B Maranville

Charles F Majkrzak

Affiliations

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Abstract

Neutron reflectometry (NR) is a powerful method for looking at the structures of multilayered thin films, including biomolecules on surfaces, particularly proteins at lipid interfaces. The spatial resolution of the film structure obtained through an NR experiment is limited by the maximum wavevector transfer at which the reflectivity can be measured. This maximum is in turn determined primarily by the scattering background, from incoherent scattering from a liquid reservoir or inelastic scattering from cell materials. Thus, reduction of scattering background is an important part of improving the spatial resolution attainable in NR measurements. Here, the background field generated by scattering from a thin liquid reservoir on a monochromatic reflectometer is measured and calculated. It is shown that background subtraction utilizing the entire background field improves data modeling and reduces experimental uncertainties associated with localized background subtraction.

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