-
., Castell, A., Browne, M., McCormack, S.J., Griffiths, P., Cabeza, L.F., (2016). Thermal energy storage in building integrated thermal systems: A review. Part 2. Integration as passive system. Renew. Energy
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shaving. Journal of Energy Storage, 32, Article 101779. Jankowiak, C., Zacharopoulos, A., Brandoni, C., Keatley, P., MacArtain, P., & Hewitt, N. (2019). The Role of Domestic Integrated Battery Energy
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(2023) ‘Experimental Characterization of the Optical Performance of Concentrating Photovoltaic Glazing (CoPVG) Systems’ Energies, 16,6. Ghoraishi, M., Hyde, T., Zacharopoulos, A., Mondol, J., Pugsley, A
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for Hydrogen Energy Applications: Advances and Challenges; Bakuru, V. R., DMello., M. E., & Kalidindi., S. B., 2019, In: ChemPhysChem 20, 1177– 1215. Optimizing Hydrogen Storage in MOFs through Engineering of
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Summary Liquid hydrogen (LH2) is the main energy carrier for future propulsion of long-haul flights and trans-ocean shipping of passenger and goods in future due to scarcity of fossil fuels such as
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pumps have key role in decarbonising heat in building sector. Heat pump integration with Photovoltaics/Thermal (PV/T) technology could provide several benefits with use of energy storage (thermal
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hydrogen storage tank. Int. J. Hydrogen Energy, 2023 (in print). https://doi.org/10.1016/j.ijhydene.2023.07.126 .
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or methanol. Additionally, energy storage and demand response technologies will play a crucial role for the energy transition. The successful PhD candidate will develop a 2050 Single Electricity Market model
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the nature of heat transfer so that we can better gauge PCMs’ ability to store heat / coolth. PCMs are a promising method of energy storage which will aid in the transition to a zero carbon, low energy