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Energy System AnalysisAuthor(s): Ekins, P., Taylor, P., Kohler, J., Page, M., Titheridge, H. and Strachan, N.
Published: 2005
Publisher: UKERC
This workshop was the first in a series of technical workshops under the Energy Systems Modelling Theme (ESMT) of the UKERC. The overall goal of these workshops is to enhance the links between UK energy modelling practitioners, and to learn about different methodologies and analytical techniques. The specific goals of this 1 st ESMT workshop on transport modelling was to bring together energy-economic and transport modellers to learn about each others models, their synergies, and to develop potential collaborations in terms of data, insights and projects. The envisaged workshop outputs were:
Author(s): ETI
Published: 2013
Publisher: ETI
Author(s): Cook, H.
Published: 2013
Publisher: ETI
Author(s): ETI
Published: 2011
Publisher: ETI
Author(s): Walker, I., Staw, T., Stewart, A. and Tiniou, E.
Published: 2016
Publisher: ETI
Author(s): ETI
Published: 2016
Publisher: ETI
Author(s): McGlade, C., Bradshaw, M., Anandarajah, G., Watson, J. and Ekins, P.
Published: 2014
Publisher: UKERC
This project uses the global TIMES Integrated Assessment Model in UCL (‘TIAM-UCL’) to provide robust quantitative insights into the future of natural gas in the energy system and in particular whether or not gas has the potential to act as a ‘bridge’ to a low-carbon future on both a global and regional basis out to 2050.
We first explore the dynamics of a scenario that disregards any need to cut greenhouse gas (GHG) emissions. Such a scenario results in a large uptake in the production and consumption of all fossil fuels, with coal in particular dominating the electricity system. It is unconventional sources of gas production that account for much of the rise in natural gas production; with shale gas exceeding 1 Tcm after 2040. Gas consumption grows in all sectors apart from the electricity sector, and eventually becomes cost effective both as a marine fuel (as liquefied natural gas) and in mediumgoods vehicles (as compressed natural gas).
We next examine how different gas market structures affect natural gas production, consumption, and trade patterns. For the two different scenarios constructed, one continued current regionalised gas markets, which are characterised by very different prices in different regions with these prices often based on oil indexation, while the other allowed a global gas price to form based on gas supply-demand fundamentals. We find only a small change in overall global gas production levels between these but a major difference in levels of gas trade and so conclude that if gas exporters choose to defend oil indexation in the short-term, they may end up destroying their export markets in longer term. A move towards pricing gas internationally, based on supply-demand dynamics, is thus shown to be crucial if they are to maintain their current levels of exports.
Author(s): Bradshaw, M.
Published: 2018
Publisher: UKERC
This briefing is based on two propositions.
First, that gas security matters, because today in the UKgas plays a dominant role in the provision of energy services, accounting for almost 40% of total inland primary energy consumption in 2017. Thus, a shortrun failure of gas security would undoubtedly have significant political and economic consequences.
Second, that the current measure is far too narrow to offer a comprehensive assessment of UK gas security, particularly in a post-Brexit context. Discussions at the Gas Security Forum suggested that:the measure of gas securityfocuses only on infrastructure capacity and not supply (capacity does not equal flow); it fails to take account of the time-lag for gas delivery; it does not measure diversity or spare capacity; it ignores the impact of multiple asset failures; and, does not consider the costs associated with ensuring greater security.
It is in this context that this paper seeks to address the following questions:
The thinking behind this paper is that a more extensive approach to measuring UK gas security is needed to address the less dramatic challenges that face UK gas security, as well as the chance of managing a Black Swanevent.
Author(s): Lowes, R., Woodman, B. and Clark, M
Published: 2018
Publisher: UKERC
This working paper considers the risks and opportunities posed to UK heat sector businesses by a potential transformation towards a low-carbon heat system in the UK. It is an output from the Heat, Incumbency and Transformations (HIT) project which is part of the UK Energy Research Centre programme.
The HIT project is investigating the idea of incumbency, considering what the term means, how it is present in the UKs heat sector and what the implications of incumbency are for the UKs potential transformation from a high carbon heat system to a low-carbon heat system.
The previous working paper developed a working definition of incumbency (Loweset al., 2017). This working paper forms the second phase of the project, exploring who the incumbents are in the UK heat system and the implications of the potential transformation for incumbents.
An online m
Author(s): Kazaglis, A., Tam, A., Eis, J., Watson, J., Hughes, N., Gross, R. and Hanna, R.
Published: 2019
Publisher: UKERC
This report, commissioned by the Aldersgate Group and co-authored with Vivid Economics, identifies out how the government can achieve a net zero target cost-effectively, in a way that enables the UK to capture competitive advantages.
The unique contribution of this report is to identify the lessons from successful and more rapid historical innovations and apply them to the challenge of meeting net zero emissions in the UK.
Achieving net zero emissions is likely to require accelerated innovation across research, demonstration and early deployment of low carbon technologies. Researchers analysed five international case studies of relatively rapid innovations to draw key lessons for government on the conditions needed to move from a typical multi-decadal cycle, to one that will deliver net zero emissions by mid-Century.
The case studies include:
The report also sets out which low carbon technologies are likely to have wider productivty and growth benefits in other industries for the UK. These include carbon capture, use and storage (CCUS); heating, ventilation and air conditioning (HVAC); wind energy; biofuels and batteries. These areas should be prioritised by the government’s innovation strategy going forwards.
Author(s): ETI
Published: 2017
Publisher: ETI
Author(s): Coleman, J. and Haslett, A.
Published: 2015
Publisher: ETI
Author(s): ETI
Published: 2017
Publisher: ETI
Author(s): ETI
Published: 2017
Publisher: ETI
These elements have only just started to penetrate energy, which has been held back significantly by the current governance structures. Energy presents similar challenges to those of finance where changes which should benefit consumers come with new risks. However, giving people more freedom in how they buy and use energy should carry less risk than giving them freedoms over their pensions and other investments.
Author(s): Chilvers, J., Pallet, H., Hargreaves, T., Stephanides, P. and Waller, L.
Published: 2022
Publisher: UKERC
Author(s): Lidstone, L.
Published: 2017
Publisher: ETI
Author(s): The CREDS Team
Published: 2019
Publisher: CREDS
Author(s): Hanna, R., Gross, R., Parrish, B. and Speirs, J.
Published: 2016
Publisher: UKERC
Author(s): Cronin, J., Pye, S., Price, J. and Butnar, I.
Published: 2020
Publisher: UKERC
This paper explores the sensitivity of energy system decarbonisation pathways to the role of afforestation and reduced energy demands as a means to lessen reliance on carbon dioxide removal.
The stringency of climate targets set out in the Paris Agreement has placed strong emphasis on the role of carbon dioxide removal (CDR) over this century. However, there are large uncertainties around the technical and economic viability and the sustainability of large-scale CDR options. These uncertainties have prompted further consideration of the role of bioenergy in decarbonisation pathways and the potential land-use trade-offs between energy crops and afforestation. The interest in afforestation is motivated by its potential as an alternative to large-scale bioenergy with carbon capture and storage (BECCS), with its arguably lower risk supply chains, and multiple co-benefits. Furthermore, doubt over the viability of large-scale CDR has prompted a renewed examination of the extent to which their need can be offset by lowering energy demands.
A global optimisation model (TIAM-UCL) was used to examine decarbonisation pathways for the global energy system. Based on core assumptions, where energy demands follow business as usual trends and degraded land is used for energy crops, the model was unable to find a solution for a 1.5°C target. Over the period 2020-2100, the carbon budget of GtCO2 is exceeded by 332 GtCO2.
Scenarios where also run to examine how the least-cost decarbonisation pathway changes if i) energy demands are significantly reduced, or ii) degraded land is used for large-scale afforestation instead of energy crops. Each option on its own reduced the CO2 budget exceedance but both were required to allow the model to meet the 1.5°C target.
Under the 2°C target, afforestation reduced the reliance on BECCS by 60%. Under the 1.5°C target, the system still used all of the biomass available, as the target is so ambitious. When the energy demands were lower, the effect of afforestation on biomass use was dependent on the climate target. Under the 2°C target, less biomass was used across all economic sectors, whereas under the stringent 1.5°C target, all the available wood and crop biomass was exploited, but its use shifted away from the production of liquid fuels towards use in power generation.
Lowering energy service demands had a larger effect on the energy mix than large-scale afforestation. This is because demands are lowered differently across the sectors according to their economic drivers. However, afforestation had a bigger impact on the marginal cost of climate change mitigation, as it substantially decreases the scale and pace of change required by the energy system, especially in the 2°C case.
Given its key role, afforestation should be considered more in deep decarbonisation scenarios, as should lower demand scenarios.
Lowering energy demand and introducing large-scale afforestation both present significant challenges and opportunities. Further work should focus on factors affecting the carbon sequestration potential of afforestation, along with an interdisciplinary research agenda on the scope for large scale energy demand reduction. Research on the social, technical and economic factors that affect the potential for converting abandoned agricultural land to energy crops or new forest would be beneficial. An interdisciplinary research agenda is needed that brings together techno-economic modelling and qualitative scenario development with research on the social change that could lead to large reductions in energy demand
Author(s): Nolden, C., Moya Mose, T., Sugar, K., Kommidi, A. and Fox, S.
Published: 2023
Publisher: UKERC
Author(s): Bell, K., Barrett, J., Ekins, P., Eyre, N., Gross, R., Watson, J. and Wright, L
Published: 2017
Publisher: UKERC
The development of a comprehensive industrial strategy for the UK is long overdue. The strategy is an opportunity to bring much needed coherence to economic and industrial policy, and to ensure that it works in tandem with the governments other policies and plans. It is particularly important that the strategy underpins the UKs transition towards a cleaner, low carbon economy. This will only be achieved if it is fully compatible with the Climate Change Act, and is integrated with the forthcoming Emissions Reduction Plan.
The Green Paper includes a welcome confirmation of the governments commitment to reducing greenhouse emissions to meet statutory targets, and to do so whilst meeting other important energy policy goals. Unlike previous statements of energy policy, we are pleased to see that the Green Paper adds a fourth policy goal alongside the familiar trilemmaof emissions r
Author(s): Chappell, J., West, A., Skippon, S., Wilkinson, P., White, M. and Willis, S.
Published: 2017
Publisher: ETI
Author(s): Beard, G., Kinnear, N., Skippon, S., Al-Katib, H., Wallbank, C., Jenkins, D., Anable, J., Stewart, A., Cluzel, C. and Dodson, T.
Published: 2017
Publisher: ETI
Author(s): Watson, J., Gross, R., Bell, K., Waddams, C., Temperton, I., Barrett, J., Rhodes, A., Gill, S. and Bays, J
Published: 2017
Publisher: UKERC
We welcome the opportunity to comment on the findings of the Cost of Energy Review, conducted by Professor Dieter Helm. In our response, we address most of the questions set out in the Call for Evidence from BEIS. Before turning to these specific questions, we have three general observations about the Review and the Call for Evidence.
First, whilst the review title focuses on the cost of energy, this is misleading. The terms of reference and the Review report make it clear that the main focus is electricity rather than energy in general.
This distinction is important since the data shows significant differences in the position of UK electricity and gas costs when compared to costs in other countries. There are also differences between relative costs for households and relative costs for business energy consumers. UK electricity prices are higher up the European league table than prices for gas. Electricity prices for energy intensive industries in the UK are particularly high.
Our second comment is that there are important distinctions between prices, costs and bills. Whilst much of the debate focuses on prices, the costs of energy for consumers also depends on their energy consumption. Therefore, it is also important to consider energy efficiency of buildings, appliances and industrial processes since these are a key determinant of costs.
Our third comment is that costs need to be considered for the electricity system as a whole. Whilst the separate questions in the Call for Evidence about generation, networks and retail supply are understandable, costs to consumers partly depend on interactions between these components of the electricity system. This compartmentalised approach to the evidence base could mean that some of these systemic interactions are missed.
Author(s): Ketsopoulou, I., Taylor, P., Watson, J., Winskel, M., Kattirtzi, M., Lowes, R., Woodman, B., Poulter, H., Brand, C., Killip, G., Anable, J., Owen, A., Hanna, R., Gross, R. and Lockwood, M.
Published: 2019
Publisher: UKERC
The in-depth analysis presented in this report focuses on four key areas of the economy, highlighting how they may need to change to remain competitive and meet future carbon targets.
The report identifies how policy makersplan for disruptions to existing systems. With the right tools and with a flexible and adaptive approach to policy implementation, decision makers can better respondto unexpected consequences and ensure delivery of key policy objectives.
Author(s): Winskel, M. and Kattirtzi, M.
Published: 2019
Publisher: UKERC
There is an increasing sense of urgency about the global energy system transition. For many observers an urgent energy transition is also a necessarily disruptive one, in that it is only by radically remaking energy systems that an accelerated transition to low carbon and sustainable energy can be achieved.
Closer to home, there has been substantial progress in some parts of the energy system in the decade since the passing of the UK and Scottish Climate Change Acts. Other areas have shown little sign of change, and the transition ahead may well be more disruptive and intrusive than that seen so far. At the same time, there is also an emerging counter-narrative: that repurposing our existing energy assets (physical and social) offers the best and quickest transition path, since there is insufficient time to disrupt and remake.
Attending energy events and keeping up-to-date with emerging evidence can instil a sense of different experts talking past each other. For those involved in whole systems energy research, and working at the research-policy interface, this can be deeply frustrating. To help address this, UKERC – working with ClimateXChange (CXC), Scotland’s Centre of Expertise on Climate Change – has spent two years analysing disruption and continuity in the UK energy system.
As part of that work, we surveyed around 130 experts and stakeholders about disruption and continuity-led change in the UK energy transition. The experts were mostly UK based researchers working on ‘whole systems’ research projects, but also included policymakers, advisory bodies, think tanks, businesses (old and new) and civil society organisations. This report presents the results of this survey work.
Author(s): Milne, S.
Published: 2015
Publisher: ETI
Author(s): Heaton, C.
Published: 2014
Publisher: ETI
Author(s): ETI
Published: 2016
Publisher: ETI
Author(s): ETI
Published: 2015
Publisher: ETI
Author(s): Day, G.
Published: 2015
Publisher: ETI
Author(s): Middleton, M.
Published: 2016
Publisher: ETI
Author(s): Bell, K., Blyth, W., Bradshaw, M., Green, R., Gross, R., Jansem, M., Ostrovnaya, A. and Webb, J.
Published: 2022
Publisher: UKERC
Author(s): Hitachi, EDF Energy, Imperial College London, Element Energy
Published: 2013
Publisher: ETI
Author(s): Batterbee, J.
Published: 2013
Publisher: ETI
Author(s): Hitachi, EDF Energy, Imperial College London, Element Energy
Published: 2013
Publisher: ETI
Author(s): ETI
Published: 2012
Publisher: ETI
Author(s): Day, G.
Published: 2016
Publisher: ETI
Author(s): Subtheme Group
Published: 2019
Publisher: Department of Business, Energy and Industrial Strategy
Author(s): Pye, S., Sabio, N. and Strachan, N.
Published: 2014
Publisher: UKERC
Policy goals to transition national energy systems to meet decarbonisation and security goals must contend with multiple overlapping uncertainties. These uncertainties are pervasive through the complex nature of the system, and exist in a strategic policy area where the impact of investment decisions have long term consequences. Uncertainty also lies in the tools and approaches used, increasing the challenges of informing robust decision making. Energy system studies in the UK have tended not to address uncertainty in a systematic manner, relying on simple scenario or sensitivity analysis. This paper utilises an innovative energy system model, ESME, which characterises multiple uncertainties via probability distributions and propagates these uncertainties to explore trade-offs in cost effective energy transition scenarios. A global sensitivity analysis is then undertaken to explore t
Author(s): Hamilton. K
Published: 2023
Publisher: UKERC
Author(s): Heaton, C and Milne, S.
Published: 2016
Publisher: ETI
Author(s): Jones Lang LaSalle Ltd (JLL)
Published: 2018
Publisher: ETI
Author(s): Bates, C.
Published: 2018
Publisher: ETI
Author(s): Jones Lang LaSalle Ltd (JLL)
Published: 2018
Publisher: ETI
Author(s): Mee, D
Published: 2018
Publisher: ETI
Author(s): Strachan, N., Kannan, R. and Pye, S.
Published: 2007
Publisher: UKERC
This is the UKERC working paper.
This is the final report for the DTI and DEFRA on the development of a new UK MARKAL & MARKAL-Macro (M-M) energy systems model. The focus of this final report is on the extensive range of UK 60% CO2 abatement scenarios and sensitivity analysis run for analytical insights to underpin the 2007 Energy White Paper. This analysis was commissioned by the DTI to underpin the development of the 2007 UK Energy White Paper, and this technical report is a companion publication to the policy focused discussion of the modelling work (DTI, 2007).
Author(s): Strachan, N., Kannan, R. and Pye, S.
Published: 2007
Publisher: PSI and UKERC
This is the final report for the DTI and DEFRA on the development of a new UK MARKAL & MARKAL-Macro (M-M) energy systems model. The focus of this final report is on the extensive range of UK 60% CO2 abatement scenarios and sensitivity analysis run for analytical insights to underpin the 2007 Energy White Paper. This analysis was commissioned by the DTI to underpin the development of the 2007 UK Energy White Paper, and this technical report is a companion publication to the policy focused discussion of the modelling work (DTI, 2007).
Author(s): Wilson, G. and Rowley, P.
Published: 2019
Publisher: UKERC
This briefing note describes the amount of gas contained within Great Britain’s gas transmission and distribution networks, and how this changes over a day to support variations in demand. The hourly data covers the 63-month period from 2013-01-01 to 2018-03-07.
The amount of gas contained within the higher-pressure tiers of Britain’s gas transmission and distribution network is termed ‘linepack’; literally, it is the amount of gas packed into the pipelines.
Linepack is proportional to the pressure of the gas in the pipelines, increasing the pressure increases the amount of gas, and thus the energy contained therein. The amount of linepack changes throughout the day due to the varying levels of pipeline pressure. This flexing of pressure provides a method to help match the supply and demand for gas within a day.
The scale of energy that can be stored and released by varying linepack highlights its importance as a means of operational flexibility, helping to balance the changes in national primary energy demand.
The scale of the within-day flexibility currently provided by the natural gas transmission and distribution networks points to a formidable energy systems challenge; how to provide low-carbon within-day flexibility to future energy systems at a reasonable cost.
Author(s): Shove, E.
Published: 2018
Publisher: CREDS
Author(s): Stabler, L. and Foulds, C.
Published: 2020
Publisher: UKERC
At present, Governments commitment stands in sharp contrast with its inaction on heat decarbonisation to date. Under pressure to progress this agenda, Government has charged the Clean Heat Directorate with the task of outlining the process for determining the UK’s long-term heat policy framework, to be published in the Roadmap for policy on heat decarbonisation in the summer of 2020 (BEIS, 2017). This report, resulting from one of six EPSRC-funded secondments, is designed to support early thinking on the roadmap by answering the research question: How can Transitions research informs the roadmap for governing the UKs heating transition?
Delivered as part of the Energy-PIECES project, this report was developed during a secondment with BEIS.
Author(s): ETI
Published: 2014
Publisher: ETI
Author(s): AECOM Ltd
Published: 2017
Publisher: ETI
Author(s): Clarke, D.
Published: 2016
Publisher: ETI
Author(s): Barrett, M. and Gallo Cassarino, T.
Published: 2021
Publisher: CREDS
Author(s): Crawley, J., Ogunrin, S., Taneja, S., Vorushlyo, I. and Wang, X.
Published: 2020
Publisher: UKERC
Author(s): Gkogka, A. and Cooke, H.
Published: 2016
Publisher: ETI
Author(s): Romero, P. and Cooke, H.
Published: 2016
Publisher: ETI
Author(s): Gkogka, A. and Cooke, H.
Published: 2016
Publisher: ETI
Author(s): Romero, P. and Cooke, H.
Published: 2016
Publisher: ETI
Author(s): Gross, R., Bradshaw, M., Blyth, W., Bell, K., Webb, J., Taylor, P., Gailani, A., Rattle, I., Cooper, S., Allen, S., Brand, C., Strachan, N., Wu, J., Qadrdan, M., Britton, J., Dodds, P., Bays, J., Jones, C., Halliday, J., Armstrong, A., Chilvers, J. and Pallet, H.
Published: 2024
Publisher: UKERC
Author(s): Britton, J. and Webb, J.
Published: 2022
Publisher: UKERC
Author(s): Cox, E., Bell, K.. and Brush, S.
Published: 2022
Publisher: UKERC
Author(s): Tingey, M., Webb, J., and Hawkey, D.
Published: 2017
Publisher: UK Energy Research Centre, the Energy Technologies Institute and the University of Edinburgh
Author(s): Brown, D., Jaccarini, C., Foxon, T., Mininni, G., Copeland, C., Brisbois, M.C., Stack- Maddox, S., Aguirre Martinez, B. and Lacey-Barnacle, M.
Published: 2023
Publisher: CREDS
Author(s): Ekins. P., Keppo. I., Skea. J., Strachan. N., Usher. W. and Anandarajah. G.
Published: 2013
Publisher: UKERC
This briefing draws out the key messages from the UKERC report The UK Energy System in 2050: comparing low-carbon resilient scenarios, – which describes and compares a series of model runs, implemented through the UK MARKAL modelling system, which was developed through UKERC with funding from the Research Councils’ Energy Programme. This has revealed some consistent patterns showing how the UK energy system might develop in future, which are discussed in detail in the full report.
Author(s): Oluleye, G. and Jobson, M.
Published: 2012
Publisher: ETI
Author(s): Jobson, M. and Vasquez, L.
Published: 2011
Publisher: ETI
Author(s): McKoen, K., Koch, A., Murshed, S.M., Meidl, P., Nichersu, A., Jumel, S. and Limani, B.
Published: 2010
Publisher: ETI
Author(s): Meidl, P., Sipowicz, M., Murshed, S.M., Jumel, S., Jobson, M., Oluleye, G., OHanlon, I., McKeon, K., Griessbaum, N., Nichersu, A.
Published: 2012
Publisher: ETI
Author(s): Barton, M., Kirton, A., Silletti, B., Smith, R., Gautier, L., Neeson, S., McKoen, K., McWilliam, L. and Jobson, M
Published: 2010
Publisher: ETI
Author(s): Lok, K., Adler, D., Cripps, A and Woods, P.
Published: 2011
Publisher: ETI
Author(s): Skea, J, and Ekins. P
Published: 2009
Publisher: UKERC
This report takes a whole systems approach to the development of the UK energy system over the next 40 years.
Achieving a resilient low-carbon energy system is technically and economically feasible at an affordable cost.
There are multiple potential pathways to a low-carbon economy. A key trade-off across the energy system is the speed of reduction in energy demand versus decarbonisation of energy supply. There is also a number of more specific trade-offs and uncertainties, such as the degree to which biomass, as opposed to electricity and perhaps hydrogen, is used in transport and other sectors.
Deploying new and improved technologies on the supply side will require substantially increased commitment to RD&D, the strengthening of financial incentives and the dismantling of regulatory and market barriers. A major increase in efforts to acceleratethedevelopment of
Author(s): Pallett, H., Chilvers, J. and Hargreaves, T.
Published: 2017
Publisher: UKERC
Author(s): Sharick, A. and Webb, J.
Published: 2016
Publisher: UKERC
UKERC co-hosted a meeting last month with DECC and ETI to seek input and feedback on plans for the 300 million in heat network capital expenditures announced in the government's Spending Review.Amber Sharick, UKERC Business Engagement Manager, andJan Webb, UKERC Researcher & Professor of Sociology of Organisations, University of Edinburgh, report on the discussions.
Author(s): Buckman, A.
Published: 2018
Publisher: ETI
Author(s): Chaudry M, Hawker G, Qadrdan M, Broad O, Webb J, Wade F, Britton J, Wu J.
Published: 2022
Publisher: UKERC
Author(s): Lowes, R. and Woodman, B.
Published: 2020
Publisher: UKERC
The paper investigates the importance of governance for energy system change and specifically investigates some of the areas where the UKs net zero target implies significant infrastructure change or expansion, namely in industry and associated with buildings and transport.
Author(s): Beaumont, N., Bell, K., Flower, J., Gross, R., Hanna, R., Qadrdan, M., Rhodes, A., Speirs, J., Taylor, P., Webb, J. and Wu. J.
Published: 2022
Publisher: UKERC
Author(s): Britton, J., Poulter, H. and Webb, J.
Published: 2023
Publisher: UKERC
Author(s): Coleman, J., Heaton, C., Day, G. and Milne, S.
Published: 2015
Publisher: ETI
Author(s): ETI
Published: 2015
Publisher: ETI
Author(s): Anandarajah, G., Strachan, N., Ekins, P., Kannan, R. and Hughes, N.
Published: 2009
Publisher: UKERC
This report is the first in the UKERC Energy 2050 project series. It focuses on a range of low carbon scenarios underpinned by energy systems analysis using the newly developed and updated UK MARKAL elastic demand (MED) model. Such modelling is designed to develop insights on a range of scenarios of future energy system evolution and the resultant technology pathways, sectoral trade-offs and economic implications. Long-term energy scenario-modelling analysis is characterised by deep uncertainty over a range of drivers including resources, technology development, behavioural change and policy mechanisms. Therefore, subsequent UKERC Energy 2050 reports focus on a broad scope of sensitivity analysis to investigate alternative scenarios of energy system evolution. In particularly, these alternative scenarios investigate different drivers of the UK’s energy supply and demand, and combine the twin goals of decarbonisation and energy system resilience. Future analysis includes the use of complementary macro-econometric and detailed sectoral energy models.
Author(s): Anandarajah, G., Strachan, N., Ekins, P., Kannan, R. and Hughes, N.
Published: 2008
Publisher: UKERC
This report is the first in the UKERC Energy 2050 project series. It focuses on a range of low carbon scenarios underpinned by energy systems analysis using the newly developed and updated UK MARKAL elastic demand (MED) model. Such modelling is designed to develop insights on a range of scenarios of future energy system evolution and the resultant technology pathways, sectoral trade-offs and economic implications. Long-term energy scenario-modelling analysis is characterised by deep uncertainty over a range of drivers including resources, technology development, and behavioural change and policy mechanisms. Therefore, subsequent UKERC Energy 2050 reports focus on a broad scope of sensitivity analysis to investigate alternative scenarios of energy system evolution. In particularly, these alternative scenarios investigate different drivers of the UKs energy supply and demand, and combine the twin goals of decarbonisation and energy system resilience. Future analysis includes the use of complementary macro-econometric and detailed sectoral energy models.
Author(s): Britton, J. and Webb, J.
Published: 2024
Publisher: UKERC
Author(s): Middleton, M.
Published: 2017
Publisher: ETI
Author(s): Palmer, J., LaJoie, K. and Strachan, NS.
Published: 2006
Publisher: UKERC
The 2006 Annual Energy Modelling Conference (AEMC) of the UK Energy Research Centre (UKERC) was held in Oxford UK from 5-7 December 2006. The conference theme was Quantifying Scenarios of a Low Carbon Society. The conference structure consisted of an open symposium with UK energy policy stakeholders followed by a technical modelling workshop. A particular emphasis was on developing country participation. A key output of the workshop was to define comparative modelling runs which will be a direct research output to the UK-Japan research project Developing Visions for a LowCarbon Society (LCS) through Sustainable Development.
Open Symposium
Author(s): Lidstone, L.
Published: 2017
Publisher: ETI
Author(s): Chiu, L.F. and Lowe, R.
Published: 2020
Publisher: CREDS
Author(s): Allan, G., Gilmartin, M., McGregor, P. and Swales, K.
Published: 2012
Publisher: UKERC
The aim of this paper is to describe three multi-sectoral modelling techniques, and to show how these modelling approaches have been used to quantify the economic impact of renewable energy and energy efficiency developments.
The three techniques are Input-Output (IO), Computable General Equilibrium (CGE) and Macroeconometric studies. Each is firstly detailed in a separate section. In each section we describe the nature and operation of the technique, and identify different types and sub-types (where appropriate). We then consider the data requirements of these modelling approaches and finally discuss what might be considered the strengths and weaknesses of each approach. For each modelling approach we pay particular attention to the ways in which the employment effects are estimated, as employment is arguably the most tangible economic variable.
After sections on each of the three modelling techniques, we address some general questions about their applicability and validity of each approach for understanding the quantitative impacts of renewable energy and energy efficiency improvements.
Author(s): Mitchell, C., Baker, P. and Gross, R.
Published: 2010
Publisher: UKERC
The UK Energy Research Centre welcomes this opportunity to provide input to the Ofgem consultation Project Discovery: Options for delivering secure and sustainable energy supplies. The UKERC response addresses a number of the questions posed in the consultation document. The response has been prepared by Catherine Mitchell and Phil Baker from the University of Exeter and Robert Gross from ICEPT at Imperial College. It makes a number of high level and specific points but does not seek to be exhaustive. We refer the reader also to UKERCs submission to Ofgems previous consultation over Project Discovery, in which we make a number of observations about the various scenarios considered by Ofgem. These provide some important context for the comments provided below.
Substantive points are made on a chapter by chapter basis below, with higher level issues pulled out as app
Author(s): Hughes, N., Mers, J. and Strachan, N.
Published: 2009
Publisher: UKERC
This paper is the second in a series which aims to provide insights into the use of scenarios for informing low carbon energy policy. Building on insights from a historical overview of strategic scenario planning in the first working paper of the series (Hughes, 2009), this paper reviews selected recent UK and international low carbon energy scenarios, analyses their strengths and weaknesses, and offers some suggestions for improving the strategic power of future UK low carbon energy scenarios.
This paper adopts the broad characterisation proposed in Hughes (2009), that scenario thinking is the use of the imagination to consider possible alternative future situations, as they may evolve from the present, with a view to improving immediate and near-term decision making. The three key objectives of scenario thinking identified in Hughes (2009), improving protective decision making, improving proactive decision making, and consensus building, are also highlighted.
The paper notes that from the approaches and methodologies outlined in Hughes (2009), two approaches in particular have been strongly drawn upon in the construction of low carbon energy scenarios. The first is the derivation of broadly consistent future scenarios from 'high level trends', sometimes represented within a '2x2 matrix'. The second is the concept of 'backcasting' from a normatively constructed future end point. This observation informs a three-fold typology for reviewing the low carbon energy scenarios in this paper:
Author(s): Watson, J., Bradshaw, M., Froggat, A., Kuzemko, C., Webb, J., Beaumont, N., Armstrong, A., Agnolucci, P., Hastings, A., Holland, R., Day, B., Delafield, G., Eigenbrod, F., Taylor, G., Lovett, A., Shepard, A., Hooper, T., Wu, J., Lowes, R., Qadrdan, M., Anable, J., Brand, C., Mullen, C., Bell, K., Taylor, P. and Allen, S.
Published: 2019
Publisher: UKERC
Author(s): Gross, R., Bell, K., Brand, C., Wade, F., Hanna, R., Heptonstall, P., Kuzemko, C., Froggatt, A., Bradshaw, M., Lowes, R., Webb, J., Dodds, P., Chilvers, J. and Hargreaves, T.
Published: 2020
Publisher: UKERC
In this issue of UKERCs annual Review of Energy Policy, we discuss some of the effects of COVID-19 on the energy system and how the unprecedented events of 2020 might impact energy use and climate policy in the future.
Focusing on electricity demand, transport, green jobs and skills, Brexit, heat, and societal engagement, the Review reflects on the past year and looks forward, highlighting key priorities for the Government.
Key recommendations
Electricity
The scale of investment in the power system required over the coming decade is huge. A big challenge is market design. We need a market that can incentivise investment in low carbon power and networks at least cost whilst also providing incentives for flexibility. Output from wind and solar farms will sometimes exceed demand and other timesfallto low levels. The right mix of flexible resources must be established to deal with variable output from renewables, with the right market signals and interventions in place to do this at least cost.
Mobility
The end of the sale of fossil fuel cars and vans by 2030 must be greeted with enthusiasm. Yet if this is to play its part in a Paris-compliant pathway to zero emissions, it must be one of many policy changes to decarbonise UK transport. Earlier action is paramount, and we recommend a market transformation approach targeting the highest emitting vehicles now, not just from 2030. Phasing-in of the phase-out will save millions of tons of CO2 thus reducing the need for radical action later on. The forthcoming Transport Decarbonisation Plan has a lot to deliver.
Green jobs and skills
COVID-19 recoverypackages offer the potential to combine job creation with emissions reduction. A national housing retrofit programme would be a triple win, creating jobs, reducing carbon emissions and make our homes more comfortable and affordable to heat. However, UKERC research finds that there are significant skills gaps associated with energy efficient buildings and low carbon heat. UKERC calls for a national programme of retraining and reskilling that takes advantage of the COVID downturn to re-equip building service professions with the skills needed for net zero.
Brexit
As the UK leaves the EU on the 1st January it will lose many of the advantages of integration. With new regimes for carbon pricing, trading, and interconnection yet to be agreed, there will be a high degree of uncertainty in the near to medium term. Given upward pressure on energy costs,delays to policy, and this uncertainty surrounding new rules, the overall effects of Brexit are not positive for UK energy decarbonisation.
Heat
UKERC research calls for action on heat to deliver the net zero technologies that we know work - insulating buildings and rolling out proven options. We need to end delay or speculation about less-proven options. Analysis is consistent with recent advice from the CCC that heat policy should focus on electrification whilst exploring options for hydrogen. We need to break the pattern of ad hoc and disjointed policy measures for heat and buildings, and develop a coherent, long-term strategy. This would be best achieved as an integral part of local and regional energy plans, involving local governments as coordinating agents. The aspirations for heat cant be realised unless we also take actionon the skills gap.
Societal engagement with energy
Achieving net zero in 2050 will entail significant changes to the way we live, what we eat and how we heat our homes. The COVID-19 pandemic has shown that when faced with a threat, society can change rapidly. Engaging society with the net zero transition also needs to change, it needs to be to be more ambitious, diverse, joined-up and system-wide, and recognise the many different ways that citizens engage with these issues on an ongoing basis.
Author(s): Gross, R., Bradshaw, M., Bridge, G., Weszkalnys, G., Rattle, I., Taylor, P., Lowes, R., Qadrdan, M., Wu, J., Anable,J., Beaumont, N., Hastings, A., Holland, R., Lovett, A., Shepherd, A..
Published: 2021
Publisher: UKERC
With a focus on gas and the UK continental shelf, industrial decarbonisation, heat, mobility and the environment, we look at developments both at home and internationally and ask whether the UK is a leader in decarbonisation, and if the transition is being managed as well as it could be.
Author(s): Taylor, P., Bays, J., Bradshaw, M., Webb, J., Britton, J., Bolton, R., Chaudry, M., Qadrdan, M., Wu, J., Anable, J., Brand, C., Rattle, I., Gailani, A., Bell K., Halliday, C., Shepherd, A., Watson, S., Lovett, A. and Hastings, A.
Published: 2023
Publisher: UKERC
Author(s): Watson, J., Ekins, P., Bradshaw, M., Wilson, G., Webb, J., Lowes, R., Bell, K., Demski, C., Snell, C., Bevan, M., Waddams, C., Anable, J. and Brand, C.
Published: 2018
Publisher: UKERC
As we reach the end of 2018, the scorecard for UK energy policy is mixed. Optimists can point to rapid emissions reductions, cost falls in renewables and the centrality of clean energy within the Industrial Strategy. Ten years after the Climate Change Act was passed, UK greenhouse gas emissions have fallen by 43% from the level in 1990. The UK is on the way to meeting the first three carbon budgets, and a transformation of the power sector is well underway.
However, if we turn our attention from the rear view mirror, the outlook is more pessimistic. As the Committee on Climate Change pointed out in June, there are an increasing number of policy gaps and uncertainties. If not addressed promptly, meeting future carbon budgets will be much more challenging. For some of these gaps, there is a particularly clear and immediate economic case for action.
The government needs to take urgent action to ensure that the UK continues to meet statutory emissions reduction targets, and goes further to achieve net zero emissions. This not only requires new policies to fill looming gaps in the portfolio, it also requires much greater emphasis on sharing the benefits and costs of the low carbon transition more equitably. Our main recommendations are:
Author(s): Watson, J., Ekins, P., Wright, L., Eyre, N., Bell, K., Darby, S., Bradshaw, M., Webb, J., Gross, R., Anable, J., Brand, C., Chilvers, J., and Pidgeon, N.
Published: 2016
Publisher: UKERC
This review takes stock of UK energy policy ahead of the Autumn Statement, Industrial Strategy and new Emissions Reduction Plan. Its main recommendations are:
Author(s): Strachan, Neil and Kannan, Ramachandran
Published: 2007
Publisher: UKERC
This report serves as a technical explanation of the MARKAL and MARKAL-Macro (M-M) model analysis, to be included in the 2007 Energy White Paper, of the long-term impacts and associated uncertainties of a 60% reduction in CO2 emissions by 2050. It is a companion report to the policy focused DTI report The MARKAL energy model in the 2007 Energy White Paper (DTI, 2007). Further policy focused MARKAL-Macro analysis, exploring alternate sensitivities and more stringent emission reduction targets is in Lockwood et al (2007) and DEFRA (2007).
Author(s): Ozkan, N., Watson, T., Connor, P., Axon, C., Whitmarsh, L., Davidson, R., Spence, A., Baker, P. and Xenias, D.
Published: 2014
Publisher: UKERC
‘Smart grid’ is a catch-all term for the smart options that could transform the ways society produces, delivers and consumes energy, and potentially the way we conceive of these services. Delivering energy more intelligently will be fundamental to decarbonising the UK electricity system at least possible cost, while maintaining security and reliability of supply.
Smarter energy delivery is expected to allow the integration of more low carbon technologies and to be much more cost effective than traditional methods, as well as contributing to economic growth by opening up new business and innovation opportunities. Innovating new options for energy system management could lead to cost savings of up to £10bn, even if low carbon technologies do not emerge1 . This saving will be much higher if UK renewable energy targets are achieved.
Building on extensive expert feedback and input, this report describes four smart grid scenarios which consider how the UK’s electricity system might develop to 2050. The scenarios outline how political decisions, as well as those made in regulation, finance, technology, consumer and social behaviour, market design or response, might affect the decisions of other actors and limit or allow the availability of future options. The project aims to explore the degree of uncertainty around the current direction of the electricity system and the complex interactions of a whole host of factors that may lead to any one of a wide range of outcomes. Our addition to this discussion will help decision makers to understand the implications of possible actions and better plan for the future, whilst recognising that it may take any one of a number of forms.
Author(s): Xenias, D., Axon, C., Balta-Ozkan, N., Cipcigan, L., Connor, P.M., Davidson, R., Spence, A., Taylor, G. and Whitmarsh, L.
Published: 2014
Publisher: UKERC
Smart grids are expected to play a central role in any transition to a low-carbon energy future, and much research is currently underway on practically every area of smart grids. However, it is evident that even basic aspects such as theoretical and operational definitions, are yet to be agreed upon and be clearly defined. Some aspects (efficient management of supply, including intermittent supply, two-way communication between the producer and user of electricity, use of IT technology to respond to and manage demand, and ensuring safe and secure electricity distribution) are more commonly accepted than others (such as smart meters) in defining what comprises a smart grid.
It is clear that smart grid developments enjoy political and financial support both at UK and EU levels, and from the majority of related industries. The reasons for this vary and include the hope that smart grids will facilitate the achievement of carbon reduction targets, create new employment opportunities, and reduce costs relevant to energy generation (fewer power stations) and distribution (fewer losses and better stability). However, smart grid development depends on additional factors, beyond the energy industry. These relate to issues of public acceptability of relevant technologies and associated risks (e.g. data safety, privacy, cyber security), pricing, competition, and regulation; implying the involvement of a wide range of players such as the industry, regulators and consumers.
The above constitute a complex set of variables and actors, and interactions between them. In order to best explore ways of possible deployment of smart grids, the use of scenarios is most adequate, as they can incorporate several parameters and variables into a coherent storyline. Scenarios have been previously used in the context of smart grids, but have traditionally focused on factors such as economic growth or policy evolution. Important additional socio-technical aspects of smart grids emerge from the literature review in this report and therefore need to be incorporated in our scenarios. These can be grouped into four (interlinked) main categories: supply side aspects, demand side aspects, policy and regulation, and technical aspects. A brief overview of each is provided.
Author(s): Watson, J., Winskel, M., Bell, K., Hawker, G., Webb, J., Tingey, M., Dodds, P., Chilvers, J., Pallett, H., Pidgeon, N., Demski, C., Morton, C., Scott, K., Roelich, K., Sakai, M., Cotton, I., Sambrook, K., Giesekam, J. and Barrett, J.
Published: 2017
Publisher: UKERC
UKERC welcomes the Scottish Government's energy and climate policy ambition, and applaud the valuable lead it is taking on energy. This has the potential to bring economic and social advantages - for example, the development of low carbon industrial capability with export potential and jobs, and improved air quality with associated health benefits. However, it is also important to ensure that the scale and pace of the transition minimises the additional costs for consumers. This can be achieved by supporting technological innovaiton that further reduces the costs of low carbon technologies and by maximising investments in energy efficiency.
Author(s): Britton, J. and Webb. J.
Published: 2022
Publisher: UKERC
Author(s): Bell, K., Bridge, G., Britton, J., Cooper, S., Gailani, A., Gross, R., Hanna, R., Munoz, C.C., Poulter, H., Rattle, I., Sugar, K., Turner, K., Webb, J. and Whitmee, S.
Published: 2023
Publisher: UKERC
Author(s): Winskel, M., Watson, J., Gross, R., Dodds, P. and Bell, K.
Published: 2018
Publisher: UKERC
UKERC have submitted a reponse to the Scottish GovernmentFinance and Constitution Committee's call for evidence on the Financial Memorandum that accompanies the Climate Change Bill.
This bill was introduced in May 2018 andamends the Climate Change (Scotland) Act 2009 to make provision for setting targets for the reduction of greenhouse gases emissions and to make provision about advice, plans and reports in relation to those targets.
Author(s): Gailani, A., Cooper, S., Allen, S., Taylor, P. and Simon, R.
Published: 2021
Publisher: UKERC
Author(s): Batterbee, J.
Published: 2016
Publisher: ETI
Author(s): Eyre, N and Killip, G. (eds)
Published: 2019
Publisher: CREDS
Author(s): CREDS
Published: 2019
Publisher: CREDS
Author(s): Haines, V., Lawton, C. and Spencer, J.
Published: 2014
Publisher: ETI
Author(s): Middleton, M.
Published: 2017
Publisher: ETI
Author(s): Buckman, A.
Published: 2017
Publisher: ETI
Author(s): Greenleaf, J. and Humphry, L.
Published: 2017
Publisher: ETI
Author(s): Humphry, L. and Greenleaf, J.
Published: 2016
Publisher: ETI
Author(s): Crawley, J., Higginson, S., Moore, G. and Eyre, N.
Published: 2023
Publisher: CREDS
Author(s): Tosato, G., Keay-Bright, S., Taylor, P. and Strachan, N.
Published: 2005
Publisher: UKERC
This regular ETSAP workshop, held at St Annes College, Oxford, was preceded by a focused UKERC sponsored event which examined issues in modelling future energy technology costs and choice.
The ETSAP meeting was structured around the two main themes. The first was applications of the MARKAL / TIMES model variants in specific methodological and policy focused projects. The second was presentations detailing ongoing model development and improvement in this open-source collaboration in energy system analytical tools.
Two underlying developments were discussed throughout the two days. The first was the surge of interest in scenario quantification and modelling of the options for climate change mitigation policies arising from the G8 Gleneagles Summit. ETSAP is likely to be heavily involved in this process which includes the IEA preparing a new flagship publicationon Global Energy Technology Perspectives (GETP). The first annual GETP is to be published in March 2006, will explore the role energy technologies can play in shaping long term markets and will be closely tied to results from the global MARKAL model. The second was an ongoing aim to continue to interact with key developing countries and to enhance and to link with their energy modelling capacities. This has been done through ETSAP as a whole and through bilateral contacts and this process will continue to be strengthened.
In additional to the modelling insights this workshop offered an excellent opportunity for networking and relationship building between international modelling groups. This was facilitated by the conference dinner held at St Anthonys College, Oxford.
Author(s): UKERC
Published: 2006
Publisher: UKERC
This report summarizes the key issues and outcomes from a Research Hotel on Energy Systems Modelling. This event, which included the MARKAL modelling teams of the USEPA and UKERC, together with additional external experts, was held at the Policy Studies Institute in London from February 6th to 10th, 2006.
Author(s): Friggens, S., Bell, P. Aufrance, D., Beaumont, R., Cook, D., Kaufmann, C. and Ashley, R.
Published: 2016
Publisher: ETI
Author(s): Friggens, S.
Published: 2015
Publisher: ETI
Author(s): Mott MacDonald
Published: 2014
Publisher: ETI
Author(s): ETI
Published: 2014
Publisher: ETI
Author(s): Friggens, S., Ashley, R., Bell, P. and Aufranc, D.
Published: 2016
Publisher: ETI
Author(s): Barker, T. and Jenkins K.
Published: 2007
Publisher: UKERC
One of the objectives of the research under the UKERC’s quantitative modelling effort is the review and development of models of energy use by the domestic sector. The aim of this paper is to describe version 3 of the Domestic Energy Sub-model, which models household energy use in the UK as a sub-model within the UK multisectoral dynamic model of the UK energy-environment-economy (E3) system maintained by Cambridge Econometrics MDM-E3. The paper does so by describing the structure of the model and development of different versions of the sub-model, with an outline of the appliances and thermal characteristics of domestic buildings included.
The paper then goes on to explain how households use thermal energy services and describes the characteristics of the buildings and appliances which are included in the model. Finally the paper describes the data collection methodology used to update the model’s dataset from 1995 to 2004 for version 3. Such a description allows the reader to see how the model is structured and how the results of the model are generated, based on the historical data.
Author(s): Qadrdan, M., Woodman, B. and Wu, J.
Published: 2023
Publisher: UKERC
Author(s): Cairney, P., Munro, F., McHarg, A., McEwen, N., Turner, K. and Katris, A.
Published: 2019
Publisher: UKERC
This briefing paper uses the example of a changing UK/Scottish government relationship after Brexit to demonstratehow to analyse the role of politics and policymaking in the transformation of energy systems.
Brexit will create a new division of policymaking responsibilities between EU, UK, and devolved governments.
In this paper we divide energy policy competences according to levels of government. Initially, it suggests that we cangenerate a clear picture of multi-level policymaking. However, the formal allocation of competences only tells a partialstory, because actual powers may operate differently from the strict legal picture. These blurry boundaries betweenresponsibilities may be further complicated by Brexit, even if it looks like the removal of a layer of government willsimplify matters.Instead of imagining clearlines of accountability, think of energy policy as part of a complex policymaking system in which the link between powers, practices, and outcomes is unclear and an energy system, in which government isonly one of many influences on outcomes.
Key findings
Author(s): Barker, Terry and Foxon, Tim
Published: 2008
Publisher: UKERC
The study examines the macroeconomic rebound effect for the UK economy, arising from UK energy efficiency policies and programmes for 2000-2010. The work explores the relationships between energy efficiency, energy consumption, economic growth and policy interventions using a well-established and highly detailed macroeconomic model of the UK economy. The work has been carried out in response to a call from the UK Department for Environment, Food and Rural Affairs (Defra), with the support of Defra’s energy-efficiency policy team. As the focus of this study is to assess the magnitude of the macroeconomic rebound effect, the projections given in the report should not be taken as forecasts of future UK economic or environmental performance, e.g. the projections given here will differ from those in the 2006 Climate Change Programme.
Author(s): Ekins, P., Keppo, I., Skea, J., Strachan, N., Usher, W. and Anandarajah, G.
Published: 2013
Publisher: UKERC
Phase 1 of the UK Energy Research Centre (UKERC) facilitated the development of a state-of-the-art MARKAL model of the UK energy system. MARKAL is a well established linear optimisation, energy system model, developed by the Energy Technology Systems Analysis Programme (ETSAP) of the International Energy Agency (IEA) in the 1970s, and was until very recently used by it for its annual Energy Technology Perspectives (ETP) reports. It is also used by many other research teams round the world, and has been regularly updated and improved over the years through the ETSAP Implementing Agreement.
Towards the end of UKERCs Phase 1, in 2007-8, UK MARKAL was used for a major modelling exercise of different projections of the UK energy system to 2050, the results of which were published in Skea at al 2011. In the ensuing years, UK MARKAL was again used for major 2050-focused modelling projects: for the Committee on Climate Change (CCC) in 2010 (CCC 2010), for the Department of Energy and Climate Change (DECC) in 2011 (HMG 2011), and again for UKERC to update the Energy 2050 scenarios in 2012. This UKERC Research Report presents the main results of each of these modelling exercises, with a view to drawing out any key messages from the set as a whole.
Comparisons between such model runs, even of the same model, need to be drawn with care. Various assumptions, including cost and other data inputs to the model, were changed between the model runs, to reflect policy and other developments, and to incorporate new information. Some of the technology representations in the model were also improved. These changes have two implications for comparisons between such model runs. The first is that detailed conclusions about the cost-preferability of particular technologies, unless they emerge as clear favourites across the whole set of runs, are unlikely to be robust. This is because the cost uncertainties of possible developments in these technologies and their competitors over four decades are very great. Where, as will be seen in these cases, the costs between the major low-carbon technologies are, or may be, of the same orderof magnitude, then there are no strong grounds on the basis of these runs of preferring one over the others on cost grounds.
The second conclusion is more positive. Where consistent patterns of development of the energy system emerge across the different runs, despite the different inputs and the fact that the runs were carried out by different modellers and modelling teams, then more confidence may be placed in these patterns as likely features of the future UK energy system under the constraints applied, theprincipal constraint being reductions in greenhouse gas (GHG) emissions, or carbon dioxide (CO2) emissions in the case of the UK energy system, according to the provisions of the UK Climate Change Act of 2008. It is these consistent patterns that inform the main conclusions of this report, which are summarised here under a number of headings. The numbers on which these broad conclusions are based appear in the main report.
Author(s): Allan, G., Barrett, J., Brockway, P., Sakai, M., Hardt, L., McGregor, P.G., Ross, A.G., Roy, G., Swales, K. and Turner, K.
Published: 2019
Publisher: UKERC
This study investigates how an increase in exports (a key pillar in the UK Industrial Strategy) could impact energy and industrial policy by comparing two types of energy-economy models.
Achieving the targets for reducing greenhouse gas emissions set out in the UK Climate Change Act will require a significant transformation in the UK's energy system.
At the same time, the government is pursuing a new UK Industrial Strategy, which aims to improve labour productivity, create high-quality jobs and boost exports across the UK.
The economic and the energy systems in the UK are tightly linked and so policies adopted in one area will produce spillover effects to the other.
To achieve the objectives set out in the two strategies it is therefore vital to understand how the policies in the energy system will affect economic development and vice versa.
Our study contributes to this by investigating how an increase in exports (a key pillar in the UK Industrial Strategy) could impact energy and industrial policy.
We address this question by systematically comparing the results of two types of energy-economy models of the UK, a computable general equilibrium model (CGE) and a macroeconometric (ME) model.
In both models we analyse a stimulus to demand from an increase in exports arising from a successful export strategy as motivated by the UK Industrial Strategy.
The qualitative results of the export stimulus are similar across all models in that GDP and employment are always stimulated. In this sense, the results are reassuring for the UK’s Industrial Strategy that emphasises export promotion.
However, the models also find that total energy use and CO2 emissions increase, and so does the energy intensity and emissions intensity of GDP.
The increase in CO2 emissions occur because the study identifies the energy and CO2 impacts of an export shock with other things remaining unchanged. Therefore the models do not simultaneously incorporate the UK carbon budgets or policies to support energy efficiency and decarbonisation of energy supplies.
However, our analysis reveals the likely adjustment of energy and climate policies to counteract the increase in CO2 and energy intensity that may result from export promotion. It therefore emphasises the need to complement UK industrial policies with appropriate action on energy use and carbon emissions to meet statutory carbon targets set by the Climate Change Act (2008).
The results highlight the interdependence of the energy and economic systems. They show that there are benefits to coordinating strategic initiatives aimed at stimulating economic activity with those aimed at tackling carbon emissions, as envisaged in the UK’s Clean Growth Strategy.
Author(s): Chaudry, M., Qadrdan, M., Chi, L. and Wu, J.
Published: 2022
Publisher: UKERC
Author(s): Cox, E., Rostston, S. and Selby, J.
Published: 2016
Publisher: UKERC
Author(s): Middleton, M.
Published: 2018
Publisher: ETI
Author(s): Middleton, M.
Published: 2017
Publisher: ETI
Author(s): Blyth, W., Gross, R., Jansen, M., Rickman, J., MacIver, C. and Bell, K.
Published: 2023
Publisher: UKERC
This working paper is an update to our November 2021 briefing paper: Risk and investment in zero-carbon electricity markets.
Author(s): Knight. R.
Published: 2016
Publisher: ETI
Author(s): ETI
Published: 2013
Publisher: ETI
Author(s): Watson, J., Gross, R., Ketsopoulou, I. and Winskel, M.
Published: 2014
Publisher: UKERC
This report examines the key uncertainties facing the UK’s planned low carbon transition, and identifies policies and strategies to mitigate or better understand them. It focuses on technical, economic, political and social uncertainties that could affect the achievement of agreed climate change targets between now and 2030.
The report shows that action can be taken to mitigate many of these uncertainties. In cases where it is not possible to significantly reduce them – at least in the short term – complementary strategies can be pursued. These include providing support for a diverse range of potential technologies and measures, and using trials and evaluations to identify those that are most effective. They also include making greater use of analytical tools that improve understanding of uncertainties and their potential impacts.
Author(s): Lidstone, L.
Published: 2016
Publisher: ETI
Author(s): Brand, C.
Published: 2010
Publisher: Environmental Change Institute, Oxford
Bridging the gap between short-term forecasting and long-term scenario models, the UK Transport Carbon Model (UKTCM) is a strategic transport, energy, emissions and environmental impacts model, covering a range of transport-energy-environment issues from socio-economic and policy influences on energy demand reduction through to lifecycle carbon emissions and external costs.
Developed partly under the auspices of the UK Energy Research Centre (UKERC) the UKTCM can be used to develop transport policy scenarios that explore the full range of technological, fiscal, regulatory and behavioural change policy interventions to meet UK climate change and energy security goals.
Author(s): Abeysekera, M., Fuentes Gonzalez, F., Gross, R., Lowes, R., Qadrdan, M. and Wu, J.
Published: 2020
Publisher: UKERC
The UK Energy Research Centre (UKERC) has provided research and analysis across the whole energy system since 2004, with funding provided by the Research Councils through a succession of five year phases. Research related to low carbon heat became a significant focus during Phase 3 (2014 2019) and the current Phase 4 includes a research theme devoted to decarbonisation of heating and cooling, with several of our other themes providing relevant insights. Our whole systems research programme addresses the challenges and opportunities presented by the transition to a net zero energy system and economy.
In this submission we address specific consultation questions where UKERC evidence and analysis provides us with relevant insights. In addition there are a number of high level observations that we provide in these introductory remarks.
Overall, we are concerned that the measures outlined in the consultation need to be set within a coherent and ambitious package of policies that work together to drive the UKs transformation to sustainable heating at a rate commensurate with the goal of net-zero by 2050. While we appreciate there are some uncertainties over the future role of the gas grid and the potential for hydrogen for heating, immediate progress in heat system decarbonisation is clearly required as part of this multi-decadal transformation. As the consultation notes, heat pumps offer a low regrets option in some applications and it is widely acknowledged that the UK has a small supplier base and very low level of heat pump deployment compared to many countries. Increasing consumer and installer familiarity, and growing the skills base and supply chain all feature strongly in the process of learning by doing that reduces heat pump costs. Ifheat pump deployment were to proceed linearly to 2050 in line with some scenarios for deployment, annual installations would need to increase by an order of magnitude. Whilst welcome, the current proposals are not sufficient to deliver a large scale market for heat pumps. Ambition and clarity of purpose are essential if heat system decarbonisation is to succeed. We also stress the importance of providing support to support the development of large low carbon heating systems, including systems attached to heat networks. We appreciate that the provisions laid out in the consultation pertain only to specific schemes and note the observations made in the consultation about support for heat networks.
Alongside the required policy changes necessary to support specific heating technologies, wider governance changes will be needed to drive the UK transformation to low carbon heating.Whilst regulation and other forms of financial support for building efficiency improvement are noted in the consultation, we note that it is likely to be important to use sticks as well as carrots if the highest carbon heating systems are to be removed and building efficiency increased. However, it will also be important to consider ownership and regulation of heat networks, the role of local authorities and opportunities for innovation that may be unlocked through regulatory change such as encouraging electricity suppliers to offer smart heating tariffs or enabling community ownership of heat distribution schemes.
While we appreciate these issues are beyond the scope of the current consultation, it is important that these considerations inform policy choices made now.
Author(s): Strachan, N.
Published: 2011
Publisher: UKERC
This UKERC Research Landscape provides an overview of the competencies and publicly funded activities inEnergy Systems Modelling research, development and demonstration (RD&D) in the UK. It covers the main funding streams, research providers, infrastructure, networks and UK participation in international activities.
UKERC ENERGY RESEARCH LANDSCAPE: ENERGY SYSTEMS MODELLING
Author(s): McDowall, W., Trutnevyte, E., Tomei, J., and Keppo, I.
Published: 2014
Publisher: UKERC
The UKERC Systems Theme has played an important role in the development of the UK’s capacity to think systematically about the future of the energy system. Key tools in this process have been the development of scenarios, and the development and use of the MARKAL energy system model. This project reflects on scenarios and on the use and communication of MARKAL, with a view to informing future UKERC work. Specifically, the project conducted retrospective analysis of pre-UKERC energy scenarios for the UK (published from 1977-2002), examined the scenarios produced by the UKERC systems theme, and studied the use and communication of the UK MARKAL model.
The diversity of scenario methods and approaches developed within UKERC is valuable, and should be fostered further. Too narrow a range of techniques and teams developing scenarios would risk constraining the ability of UKERC to open up thinking to a wide range of possibilities, perspectives and framings, which history suggests is important. UKERC scenarios have tended to be dominated by futures in which mitigation goals are met, and in which scenario differences are driven by policy or technology, though there are of course exceptions. As UKERC Phase 3 begins, there is a case for reflecting further on the range and type of uncertainties addressed within energy system scenarios, and the diversity of tools and techniques used to generate them.
A core tool of the UKERC systems theme has been the UK MARKAL model. The research undertaken for this project indicates that MARKAL has generally been used and communicated appropriately, in part because of good working relationships between government analysts and UKERC researchers. There are also areas in which there is room for improvement, and UKERC Phase 3 provides an opportunity to learn the lessons from previous experience.
Author(s): UKERC
Published: 2020
Publisher: UKERC
The UK Energy Research Centre (UKERC) is in its fourth five-year phase of research and engagement activities, which will run until April 2024. In addition to the core programme of research, a number of mechanisms have been put in place to ensure that participation in UKERC is broad, flexible and addresses the needs of the wider UK research community.
A Flexible Fund of around £3m (valued at 80% FEC) has been set up in order to commission new research and facilitate the integration of the existing programme. The Fund is overseen by UKERC’s independent Research Committee. The key aims of the Fund are:
This report presents the outputs of two key consultation activities on potential Flexible Fund topics :
Author(s): Chaudry. M., Usher. W., Ekins. P., Strachan. N., Jenkins. N., Baker. P., Skea. J. and Hardy J
Published: 2009
Publisher: UKERC
Author(s): Eyre, N. and Baruah, P.
Published: 2014
Publisher: UKERC
Direct use of fossil fuels is the main source of space heating in the UK and this drives a major part of national greenhouse gas emissions. Climate stabilisation therefore implies a systemic change in approaches to space heating, involving some combination of radical efficiency improvement and low carbon fuels. The challenge in this area for the UK is made particularly difficult because of the combination of the legal commitment to an 80% reduction in emissions by 2050, an old building stock and a very high penetration of natural gas as a heating fuel.
This paper presents new quantified scenarios for residential energy use in the UK to 2050. These address both factors that are exogenous to the energy system, such as population, but also some systemically different approaches to delivering residential heat.
Author(s): Braunholtz-Speight, T., McLachlan, C., Mander, S., Cairns, I., Hannon, M., Hardy, J., Manderson, E. and Sharmina, M
Published: 2019
Publisher: UKERC
What might community energy in the UK look like in the long term ? What does it need for it to thrive ?
This report provides a summary of practitioner and stakeholder responses to these questions, and many more, that explore the future of community energy in the UK.
Through a series of workshops held across the UK over the winter of 2018-19, invited participants were encouraged to explore and debate the future of community energy.
We found that community energy actors feel they have lots to offer to, and gain from, the transition to a decentralised and flexible energy system. The system appears to be moving towards a future where there is a clear need for organisations that combine technical knowledge with the skills and trust to effectively engage citizens – such as community energy groups.
Author(s): Favaro, A. and Zhihan Xu
Published: 2017
Publisher: ETI
Author(s): De la Cruz, M.
Published: 2017
Publisher: ETI
Author(s): Korais, E.
Published: 2017
Publisher: ETI
Author(s): Ove Arup and Partners Ltd
Published: 2017
Publisher: ETI
Author(s): Ove Arup and Partners Ltd
Published: 2017
Publisher: ETI
Author(s): Ove Arup and Partners Ltd
Published: 2017
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2018
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2018
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2016
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2016
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2018
Publisher: ETI
This document sets out the evidence base in support of a local energy strategy for Bury.
Key conclusions
Author(s): Korais, E.
Published: 2017
Publisher: ETI
Author(s): Korais, E.
Published: 2017
Publisher: ETI
Author(s): Korais, E.
Published: 2018
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2016
Publisher: ETI
Author(s): Energy Systems Catapult
Published: 2018
Publisher: ETI
Author(s): Tingey, M., Braunholtz-Speight, T., Hawkey, D., McLachlan, C. and Webb, J.
Published: 2018
Publisher: UKERC
We welcome the Welsh Government’s interest in locally owned renewable energy. Our response draws on a range of research undertaken by the Heat and the City research group at the University of Edinburgh, including a UK-wide study of local authorities and energy; and on the Financing Community Energy research project being led by Tyndall Manchester.
In our response we made the following general comments, before responding to individual points raised in the call:
Author(s): Hampton, S., Eadson, W., Blundel, R. and Sugar, K.
Published: 2024
Publisher: UKERC
Author(s): Clarke, D.
Published: 2016
Publisher: ETI
Author(s): Strachan, N. and Ozkan, N.
Published: 2005
Publisher: UKERC
This workshop brought together researchers working within the International Energy Agency’s ETSAP network of MARKAL model users, together with a broad range of practitioners from the UK energy modelling community.
This opportunity for the two modelling communities to learn from each other’s work was enabled by the UK hosting the regular ETSAP semi-annual meeting which discussed modelling issues related to the MARKAL / TIMES family of energy models on subsequent days. One of the purposes of the UKERC Meeting Place is to develop networking and collaboration between UK energy researchers and also with the wider network of international energy practitioners.
The costs and characteristics of future energy technologies and how quickly they penetrate markets is a fundamental driver in the evolution of energy systems. Future technology cost is critical in assessing the costs of energy policies, ranging from economic competitiveness, environmental protection and emission mitigation, security of supply and equitable access to energy services. In response, a major ongoing effort by the energy modelling community has sought to better understand and incorporate this key driver of technological change into their energy models.
The scope of the workshop was to:
Author(s): ETI
Published: 2016
Publisher: ETI
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