Realising transition pathways for a more electric, low carbon energy system in the UK : challenges, insights and opportunities
Chilvers, Jason and Foxon, Timothy J and Galloway, Stuart and Hammond, Geoffrey P. and Infield, David and Leach, Matthew and Pearson, Peter JG and Strachan, Neil and Strbac, Goran and Thomson, Murray (2017) Realising transition pathways for a more electric, low carbon energy system in the UK : challenges, insights and opportunities. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy. ISSN 0957-6509 (https://doi.org/10.1177/0957650917695448)
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Abstract
The United Kingdom (UK) has placed itself on a transition towards a low carbon economy and society, through the imposition of a legally-binding goal aimed at reducing its ‘greenhouse gas’ (GHG) emissions by 80% by 2050 against a 1990 baseline. A set of three low-carbon, sociotechnical transition pathways were developed and analysed via an innovative collaboration between engineers, social scientists and policy analysts. The pathways focus on the power sector, including the potential for increasing use of low-carbon electricity for heating and transport, within the context of critical European Union developments and policies. Their development started from narrative storylines regarding different governance framings, drawing on interviews and workshops with stakeholders and analysis of historical analogies. The quantified UK pathways were named Market Rules (MR), Central Co-ordination (CC) and Thousand Flowers (TF); each reflecting a dominant logic of governance arrangements. The aim of the present contribution was to use these pathways to explore what is needed to realise a transition that successfully addresses the so-called energy policy 'trilemma', i.e., the simultaneous delivery of low carbon, secure and affordable energy services. Analytical tools were developed and applied to assess the technical feasibility, social acceptability, and environmental and economic impacts of the pathways. Technological and behavioural developments were examined, alongside appropriate governance structures and regulations for these low-carbon transition pathways, as well as the roles of key energy system 'actors' (both large and small). An assessment of the part that could possibly be played by future demand side response (DSR) was also undertaken in order to understand the factors that drive energy demand and energy-using behaviour, and reflecting growing interest in DSR for balancing a system with high proportions of renewable generation. A set of interacting and complementary engineering and techno-economic models or tools were then employed to analyse electricity network infrastructure investment and operational decisions to assist market design and option evaluation. This provided a basis for integrating the analysis within a whole systems framework of electricity system development, together with the evaluation of future economic benefits, costs and uncertainties. Finally, the energy and environmental performance of the different energy mixes were appraised on a ‘life-cycle’ basis to determine the GHG emissions and other ecological or health burdens associated with each of the three transition pathways. Here the challenges and opportunities that have been identified over the transition towards a low-carbon future in the UK are described with the purpose of providing a valuable evidence base for developers, policy makers, and other stakeholders.
ORCID iDs
Chilvers, Jason, Foxon, Timothy J, Galloway, Stuart ORCID: https://orcid.org/0000-0003-1978-993X, Hammond, Geoffrey P., Infield, David, Leach, Matthew, Pearson, Peter JG, Strachan, Neil, Strbac, Goran and Thomson, Murray;-
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Item type: Article ID code: 61815 Dates: DateEvent26 March 2017Published26 March 2017Published Online31 January 2017AcceptedSubjects: Technology > Mechanical engineering and machinery Department: Faculty of Engineering > Electronic and Electrical Engineering
Strategic Research Themes > Energy
Strategic Research Themes > Measurement Science and Enabling TechnologiesDepositing user: Pure Administrator Date deposited: 21 Sep 2017 14:12 Last modified: 03 Dec 2024 05:06 URI: https://strathprints.strath.ac.uk/id/eprint/61815