Multiscale in-situ characterisation of degradation and reactivity in solid oxide fuel cells
Lead Research Organisation:
University College London
Department Name: Chemical Engineering
Abstract
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Organisations
People |
ORCID iD |
Daniel Brett (Principal Investigator) |
Publications
Robinson J
(2016)
Thermal Imaging of Electrochemical Power Systems: A Review
in Journal of Imaging
Meyer Q
(2015)
System-level electro-thermal optimisation of air-cooled open-cathode polymer electrolyte fuel cells: Air blower parasitic load and schemes for dynamic operation
in International Journal of Hydrogen Energy
Obeisun O
(2015)
Study of water accumulation dynamics in the channels of an open-cathode fuel cell through electro-thermal characterisation and droplet visualisation
in International Journal of Hydrogen Energy
Maher RC
(2016)
Reduction Dynamics of Doped Ceria, Nickel Oxide, and Cermet Composites Probed Using In Situ Raman Spectroscopy.
in Advanced science (Weinheim, Baden-Wurttemberg, Germany)
Meyer Q
(2015)
Optimisation of air cooled, open-cathode fuel cells: Current of lowest resistance and electro-thermal performance mapping
in Journal of Power Sources
Tjaden B
(2016)
On the origin and application of the Bruggeman correlation for analysing transport phenomena in electrochemical systems
in Current Opinion in Chemical Engineering
Robinson J
(2014)
Non-uniform temperature distribution in Li-ion batteries during discharge - A combined thermal imaging, X-ray micro-tomography and electrochemical impedance approach
in Journal of Power Sources
Toleuova A
(2016)
Mechanistic Studies of Liquid Metal Anode SOFCs II: Development of a Coulometric Titration Technique to Aid Reactor Design
in Chemical Engineering Science
Description | So far this project has allowed us to develop correlative metrology techniques for the analysis of solid oxide fuel cells. This includes the ability to examine the temperature distribution in electrode materials and relate this to strain within the structure. We have also developed an in-situ SOFC cell capable of viewing, with an infrared thermal camera, the temperature distribution within an operational system. We will use these results to inform model development in the next phase of work. |
Exploitation Route | Our thermal imaging technique will provide unparalleled insight into the internal workings of SOFCs and allow advanced models describing electro-thermal operation to be developed and validated, so leading to the development of commercial SOFC technology. |
Sectors | Energy |
URL | http://www.ucl.ac.uk/electrochemical-innovation-lab |
Description | Findings of the operation of solid oxide fuel cell materials under thermal gradients are being communicated to out industrial collaborator, Ceres Power, and we have recently applied for a Supergen H2FC Early Career Researcher award with Ceres to apply thermal imaging alongside X-ray computed tomography to help understand how electrodes function in devices. |
First Year Of Impact | 2014 |
Sector | Energy,Environment |
Impact Types | Societal,Economic |