Decarbonising electrical grids using photovoltaics with enhanced capacity factors

Williams, Cai; Michaels, Hannes; Crossland, Andrew F.; Zhang, Zongtai; Shirshova, Natasha; MacKenzie, Roderick C. I.; Sun, Hongjian; Kettle, Jeff; Freitag, Marina; Groves, Christopher

doi:10.1039/d3ee00633f

Decarbonising electrical grids using photovoltaics with enhanced capacity factors

Williams, Cai; Michaels, Hannes; Crossland, Andrew F.; Zhang, Zongtai; Shirshova, Natasha; MacKenzie, Roderick C. I.; Sun, Hongjian; Kettle, Jeff; Freitag, Marina; Groves, Christopher

Authors

Cai Williams cai.williams@durham.ac.uk
PGR Student Doctor of Philosophy

Hannes Michaels

Andrew F. Crossland

Zongtai Zhang zongtai.zhang@durham.ac.uk
PGR Student Doctor of Philosophy

Dr Natasha Shirshova natasha.shirshova@durham.ac.uk
Associate Professor

Roderick C. I. MacKenzie

Professor Hongjian Sun hongjian.sun@durham.ac.uk
Professor

Jeff Kettle

Marina Freitag

Professor Chris Groves chris.groves@durham.ac.uk
Professor

Abstract

Many scenarios for Net Zero anticipate substantial growth of Solar PV generation to satisfy 30% of our electricity needs. However, this scale of deployment introduces challenges as supply may not meet demand, thereby necessitating energy storage and demand-side management. Here we demonstrate a different, complementary approach to resolving this challenge in which Solar PV generation can be made intrinsically less variable than commercial PV. Proof-of-concept dye-sensetised PVs for which the power conversion efficiency increases as light intensity reduces are demonstrated. Modelling of the UK mainland energy network predicts that these devices are more effective at displacing high carbon generation from coal and gas than commercial PV. The capacity factor of these PV devices are controlled by their design, and capacity factors >60% greater than silicon are predicted based on experimental data. These data demonstrate a new approach to designing PV devices in which minimising variability in generation is the goal. This new design target can be realised in a range of emerging technologies, including Perovskite PV and Organic PV, and is predicted to be more effective at delivering carbon reductions for a given energy network than commercial PV.

Citation

Williams, C., Michaels, H., Crossland, A. F., Zhang, Z., Shirshova, N., MacKenzie, R. C. I., …Groves, C. (2023). Decarbonising electrical grids using photovoltaics with enhanced capacity factors. Energy & Environmental Science, 16(10), 4650-4659. https://doi.org/10.1039/d3ee00633f

Journal Article Type	Article
Acceptance Date	Sep 7, 2023
Online Publication Date	Sep 19, 2023
Publication Date	2023
Deposit Date	Nov 2, 2023
Publicly Available Date	Nov 2, 2023
Journal	Energy & Environmental Science
Print ISSN	1754-5692
Electronic ISSN	1754-5706
Publisher	Royal Society of Chemistry
Peer Reviewed	Peer Reviewed
Volume	16
Issue	10
Pages	4650-4659
DOI	https://doi.org/10.1039/d3ee00633f
Keywords	Pollution; Nuclear Energy and Engineering; Renewable Energy, Sustainability and the Environment; Environmental Chemistry
Public URL	https://durham-repository.worktribe.com/output/1875194