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In-Situ Diffraction Studies of Gas Storage Materials on a Laboratory X-Ray System

Published online by Cambridge University Press:  07 October 2013

Marco Sommariva ,
Harald van Weeren ,
Olga Narygina ,
Jan-André Gertenbach ,
Christian Resch ,
Andreas Pein ,
Vincent J. Smith  and
Leonard J. Barbour
Marco Sommariva
Affiliation:
PANalytical B.V., Lelyweg 1, Almelo 7602 EA, The Netherlands
Harald van Weeren
Affiliation:
PANalytical B.V., Lelyweg 1, Almelo 7602 EA, The Netherlands
Olga Narygina
Affiliation:
PANalytical B.V., Lelyweg 1, Almelo 7602 EA, The Netherlands
Jan-André Gertenbach
Affiliation:
PANalytical B.V., Lelyweg 1, Almelo 7602 EA, The Netherlands
Christian Resch
Affiliation:
Anton Paar GmbH, Anton-Paar-Strasse 20, 8054 Graz, Austria
Andreas Pein
Affiliation:
Anton Paar GmbH, Anton-Paar-Strasse 20, 8054 Graz, Austria
Vincent J. Smith
Affiliation:
Stellenbosch University, Corner of De Beer and Merriman streets, Stellenbosch 7602, Republic of South Africa
Leonard J. Barbour
Affiliation:
Stellenbosch University, Corner of De Beer and Merriman streets, Stellenbosch 7602, Republic of South Africa
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Abstract

The sorption processes for hydrogen and carbon dioxide are of considerable, and growing interest, particularly due to their relevance to a society that seeks to replace fossil fuels with a more sustainable energy source. X-ray diffraction allows a unique perspective for studying structural modifications and reaction mechanisms that occur when gas and solid interact. The fundamental challenge associated with such a study is that experiments are conducted while the solid sample is held under a gas pressure. To date in-situ high gas pressure studies of this nature have typically been undertaken at large-scale facilities such as synchrotrons or on dedicated laboratory instruments. Here we report high-pressure XRD studies carried out on a multi-purpose diffractometer. To demonstrate the suitability of the equipment, two model studies were carried out, firstly the reversible hydrogen cycling over LaNi5, and secondly the structural change that occurs during the decomposition of ammonia borane that results in the generation of hydrogen gas in the reaction chamber. The results have been finally compared to the literature. The study has been made possible by the combination of rapid X-ray detectors with a reaction chamber capable of withstanding gas pressures up to 100 bar and temperatures up to 900 °C.

Keywords

hydrogenationx-ray diffraction (XRD)energy storage
Type
Articles
Information
MRS Online Proceedings Library (OPL) , Volume 1544: Symposium J – In-Situ Characterization Methods in Energy Materials Research , 2013 , mrss13-1544-j05-06
Copyright
Copyright © Materials Research Society 2013 

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