Efficient data extraction from neutron time-of-flight spin-echo raw data

P. A. Zolnierczuk; O. Holderer; S. Pasini; T. Kozielewski; L. R. Stingaciud; M. Monkenbuschc

doi:10.1107/S1600576719010847

Efficient data extraction from neutron time-of-flight spin-echo raw data

P. A. Zolnierczuk, O. Holderer, S. Pasini, T. Kozielewski, L. R. Stingaciud, M. Monkenbuschc

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

Neutron spin-echo spectrometers with a position-sensitive detector and operating with extended time-of-flight-tagged wavelength frames are able to collect a comprehensive set of data covering a large range of wavevector and Fourier time space with only a few instrumental settings in a quasi-continuous way. Extracting all the information contained in the raw data and mapping them to a suitable physical space in the most efficient way is a challenge. This article reports algorithms employed in dedicated software, DrSpine (data reduction for spin echo), that achieves this goal and yields reliable representations of the intermediate scattering function S(Q, 14;t) independent of the selected 'binning'.

Original language	English
Pages (from-to)	1022-1034
Number of pages	13
Journal	Journal of Applied Crystallography
Volume	52
DOIs	https://doi.org/10.1107/S1600576719010847
State	Published - 2019
Externally published	Yes

Keywords

Data reduction
NSE
Neutron spin echo
Spallation neutron sources

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abstract = "Neutron spin-echo spectrometers with a position-sensitive detector and operating with extended time-of-flight-tagged wavelength frames are able to collect a comprehensive set of data covering a large range of wavevector and Fourier time space with only a few instrumental settings in a quasi-continuous way. Extracting all the information contained in the raw data and mapping them to a suitable physical space in the most efficient way is a challenge. This article reports algorithms employed in dedicated software, DrSpine (data reduction for spin echo), that achieves this goal and yields reliable representations of the intermediate scattering function S(Q, 14;t) independent of the selected 'binning'.",

keywords = "Data reduction, NSE, Neutron spin echo, Spallation neutron sources",

author = "Zolnierczuk, {P. A.} and O. Holderer and S. Pasini and T. Kozielewski and Stingaciud, {L. R.} and M. Monkenbuschc",

year = "2019",

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language = "English",

volume = "52",

pages = "1022--1034",

journal = "Journal of Applied Crystallography",

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T1 - Efficient data extraction from neutron time-of-flight spin-echo raw data

AU - Zolnierczuk, P. A.

AU - Holderer, O.

AU - Pasini, S.

AU - Kozielewski, T.

AU - Stingaciud, L. R.

AU - Monkenbuschc, M.

PY - 2019

Y1 - 2019

N2 - Neutron spin-echo spectrometers with a position-sensitive detector and operating with extended time-of-flight-tagged wavelength frames are able to collect a comprehensive set of data covering a large range of wavevector and Fourier time space with only a few instrumental settings in a quasi-continuous way. Extracting all the information contained in the raw data and mapping them to a suitable physical space in the most efficient way is a challenge. This article reports algorithms employed in dedicated software, DrSpine (data reduction for spin echo), that achieves this goal and yields reliable representations of the intermediate scattering function S(Q, 14;t) independent of the selected 'binning'.

AB - Neutron spin-echo spectrometers with a position-sensitive detector and operating with extended time-of-flight-tagged wavelength frames are able to collect a comprehensive set of data covering a large range of wavevector and Fourier time space with only a few instrumental settings in a quasi-continuous way. Extracting all the information contained in the raw data and mapping them to a suitable physical space in the most efficient way is a challenge. This article reports algorithms employed in dedicated software, DrSpine (data reduction for spin echo), that achieves this goal and yields reliable representations of the intermediate scattering function S(Q, 14;t) independent of the selected 'binning'.

KW - Data reduction

KW - NSE

KW - Neutron spin echo

KW - Spallation neutron sources

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SP - 1022

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JO - Journal of Applied Crystallography

JF - Journal of Applied Crystallography

ER -

Efficient data extraction from neutron time-of-flight spin-echo raw data

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Keywords

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