Funding Information: This research is funded by Net Zero Technology Centre and the University of Aberdeen , through their partnership in the UK National Decommissioning Centre. Astley Hastings is funded by the UK Research and Innovation Energy Programme under grant number EP/S029575/1 . Publisher Copyright: © 2023 The Author(s)Peer reviewedPublisher PD
Hydrogen is important because it is one of three key zero-carbon vectors for decarbonising economies...
A global transition to hydrogen fuel offers major opportunities to decarbonise a range of different ...
AbstractNatural gas used for power generation will be increasingly sourced from more geographically ...
With a limited global carbon budget, it is imperative that decarbonisation decisions are based on ac...
Future energy systems could rely on hydrogen (H2) to achieve decarbonisation and net-zero goals. In ...
© 2020 The Authors Hydrogen has been identified as a potential energy vector to decarbonise the tran...
Climate change is mainly caused by anthropogenic emissions and can result in loss of biodiversity, p...
Green hydrogen produced from renewable energy resources can not only contribute to the decarbonisati...
Achieving the UK’s long-term climate targets will require a coordinated approach to decarbonising bo...
Green hydrogen could contribute to climate change mitigation, but its greenhouse gas footprint varie...
The urgency to achieve net-zero carbon dioxide (CO2) emissions by 2050, as first presented by the IP...
Low-carbon hydrogen can assist in addressing the global crisis of climate change by significantly de...
This report explores the costs of producing green hydrogen in Scotland, including how the production...
Projections of decarbonisation pathways have typically involved reducing dependence on natural gas g...
Green hydrogen is produced from water and solar, wind, and/or hydro energy via electrolysis and is c...
Hydrogen is important because it is one of three key zero-carbon vectors for decarbonising economies...
A global transition to hydrogen fuel offers major opportunities to decarbonise a range of different ...
AbstractNatural gas used for power generation will be increasingly sourced from more geographically ...
With a limited global carbon budget, it is imperative that decarbonisation decisions are based on ac...
Future energy systems could rely on hydrogen (H2) to achieve decarbonisation and net-zero goals. In ...
© 2020 The Authors Hydrogen has been identified as a potential energy vector to decarbonise the tran...
Climate change is mainly caused by anthropogenic emissions and can result in loss of biodiversity, p...
Green hydrogen produced from renewable energy resources can not only contribute to the decarbonisati...
Achieving the UK’s long-term climate targets will require a coordinated approach to decarbonising bo...
Green hydrogen could contribute to climate change mitigation, but its greenhouse gas footprint varie...
The urgency to achieve net-zero carbon dioxide (CO2) emissions by 2050, as first presented by the IP...
Low-carbon hydrogen can assist in addressing the global crisis of climate change by significantly de...
This report explores the costs of producing green hydrogen in Scotland, including how the production...
Projections of decarbonisation pathways have typically involved reducing dependence on natural gas g...
Green hydrogen is produced from water and solar, wind, and/or hydro energy via electrolysis and is c...
Hydrogen is important because it is one of three key zero-carbon vectors for decarbonising economies...
A global transition to hydrogen fuel offers major opportunities to decarbonise a range of different ...
AbstractNatural gas used for power generation will be increasingly sourced from more geographically ...
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