A compact time-of-flight SANS instrument optimised for measurements of small sample volumes at the European Spallation Source

Søren Kynde, Kaspar Hewitt Klenø, Gergely Nagy, Kell Mortensen, Kim Lefmann, Joachim Kohlbrecher, Lise Arleth

Research output: Contribution to journalArticlepeer-review

8 Scopus citations

Abstract

The high flux at European Spallation Source (ESS) will allow for performing experiments with relatively small beam-sizes while maintaining a high intensity of the incoming beam. The pulsed nature of the source makes the facility optimal for time-of-flight small-angle neutron scattering (ToF-SANS). We find that a relatively compact SANS instrument becomes the optimal choice in order to obtain the widest possible q-range in a single setting and the best possible exploitation of the neutrons in each pulse and hence obtaining the highest possible flux at the sample position. The instrument proposed in the present article is optimised for performing fast measurements of small scattering volumes, typically down to 2×2×2 mm3, while covering a broad q-range from about 0.005 1/Å to 0.5 1/Å in a single instrument setting. This q-range corresponds to that available at a typical good BioSAXS instrument and is relevant for a wide set of biomacromolecular samples. A central advantage of covering the whole q-range in a single setting is that each sample has to be loaded only once. This makes it convenient to use the fully automated high-throughput flow-through sample changers commonly applied at modern synchrotron BioSAXS-facilities. The central drawback of choosing a very compact instrument is that the resolution in terms of δλ/λ obtained with the short wavelength neutrons becomes worse than what is usually the standard at state-of-the-art SANS instruments. Our McStas based simulations of the instrument performance for a set of characteristic biomacromolecular samples show that the resulting smearing effects still have relatively minor effects on the obtained data and can be compensated for in the data analysis. However, in cases where a better resolution is required in combination with the large simultaneous q-range characteristic of the instrument, we show that this can be obtained by inserting a set of choppers.

Original languageEnglish
Pages (from-to)133-141
Number of pages9
JournalNuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Volume764
DOIs
StatePublished - Nov 11 2014
Externally publishedYes

Funding

We appreciate useful discussions with the ESS STAP members and Andrew Jackson (ESS). The simulation software was supported by Peter Willendrup (DTU) and the hardware by ESS Data Management and Software Centre . We owe much thank to Emmanuel Farhi (ILL) for providing us his McStas implementation of the ILL-D22 instrument model. The project has been supported by the Danish Agency of Research and Innovation by grants supporting the ESS design update.

FundersFunder number
Danish Agency of Research and Innovation
Peter Willendrup
Delhi Technological University

    Keywords

    • Bio-SANS
    • ESS
    • Macromolecules
    • McStas
    • Neutron scattering
    • SANS

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