Real-time powder diffraction studies of energy materials under non-equilibrium conditions

Real-time powder diffraction studies of energy materials under non-equilibrium conditions

Energy materials form the central part of energy devices. An essential part of their function is the ability to reversibly host charge or energy carriers, and analysis of their phase composition and structure in real time under non-equilibrium conditions is mandatory for a full understanding of thei...

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Main Authors: Vanessa K. Peterson, Josie E. Auckett, Wei-Kong Pang
Format: Article
Language:English
Published: International Union of Crystallography 2017-09-01
Series:IUCrJ
Subjects:
real-time studies
operando studies
powder diffraction
functional materials
energy materials
Online Access:http://scripts.iucr.org/cgi-bin/paper?S2052252517010363
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spelling doaj-d8197deb96e544ffb49e960f484731192020-11-24T21:05:14ZengInternational Union of CrystallographyIUCrJ2052-25252017-09-014554055410.1107/S2052252517010363ti5010Real-time powder diffraction studies of energy materials under non-equilibrium conditionsVanessa K. Peterson0Josie E. Auckett1Wei-Kong Pang2Australian Nuclear Science and Technology Organisation, Locked Bag 2001, Kirrawee DC, NSW 2232, AustraliaAustralian Nuclear Science and Technology Organisation, Locked Bag 2001, Kirrawee DC, NSW 2232, AustraliaInstitute for Superconducting and Electronic Materials, Faculty of Engineering, University of Wollongong, Wollongong, NSW 2522, AustraliaEnergy materials form the central part of energy devices. An essential part of their function is the ability to reversibly host charge or energy carriers, and analysis of their phase composition and structure in real time under non-equilibrium conditions is mandatory for a full understanding of their atomic-scale functional mechanism. Real-time powder diffraction is increasingly being applied for this purpose, forming a critical step in the strategic chemical engineering of materials with improved behaviour. This topical review gives examples of real-time analysis using powder diffraction of rechargeable battery electrodes and porous sorbent materials used for the separation and storage of energy-relevant gases to demonstrate advances in the insights which can be gained into their atomic-scale function.http://scripts.iucr.org/cgi-bin/paper?S2052252517010363real-time studiesoperando studiespowder diffractionfunctional materialsenergy materials
collection DOAJ
language English
format Article
sources DOAJ
author Vanessa K. Peterson
Josie E. Auckett
Wei-Kong Pang
spellingShingle Vanessa K. Peterson
Josie E. Auckett
Wei-Kong Pang
Real-time powder diffraction studies of energy materials under non-equilibrium conditions
IUCrJ
real-time studies
operando studies
powder diffraction
functional materials
energy materials
author_facet Vanessa K. Peterson
Josie E. Auckett
Wei-Kong Pang
author_sort Vanessa K. Peterson
title Real-time powder diffraction studies of energy materials under non-equilibrium conditions
title_short Real-time powder diffraction studies of energy materials under non-equilibrium conditions
title_full Real-time powder diffraction studies of energy materials under non-equilibrium conditions
title_fullStr Real-time powder diffraction studies of energy materials under non-equilibrium conditions
title_full_unstemmed Real-time powder diffraction studies of energy materials under non-equilibrium conditions
title_sort real-time powder diffraction studies of energy materials under non-equilibrium conditions
publisher International Union of Crystallography
series IUCrJ
issn 2052-2525
publishDate 2017-09-01
description Energy materials form the central part of energy devices. An essential part of their function is the ability to reversibly host charge or energy carriers, and analysis of their phase composition and structure in real time under non-equilibrium conditions is mandatory for a full understanding of their atomic-scale functional mechanism. Real-time powder diffraction is increasingly being applied for this purpose, forming a critical step in the strategic chemical engineering of materials with improved behaviour. This topical review gives examples of real-time analysis using powder diffraction of rechargeable battery electrodes and porous sorbent materials used for the separation and storage of energy-relevant gases to demonstrate advances in the insights which can be gained into their atomic-scale function.
topic real-time studies
operando studies
powder diffraction
functional materials
energy materials
url http://scripts.iucr.org/cgi-bin/paper?S2052252517010363
work_keys_str_mv AT vanessakpeterson realtimepowderdiffractionstudiesofenergymaterialsundernonequilibriumconditions
AT josieeauckett realtimepowderdiffractionstudiesofenergymaterialsundernonequilibriumconditions
AT weikongpang realtimepowderdiffractionstudiesofenergymaterialsundernonequilibriumconditions
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