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Oil & Gas refining, transport & storageAuthor(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): McGlade, C., Speirs, J. and Sorrell, S.
Published: 2012
Publisher: UKERC
This report assesses the currently available evidence on the size of unconventional gas resources at the regional and global level. Focusing in particular on shale gas, it provides a comprehensive summary and comparison of the estimates that have been produced to date. It also examines the methods by which these resource estimates have been produced the strengths and weaknesses of those methods, the range of uncertainty in the results and the factors that are relevant to their interpretation.
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): Wilson, G., Taylor, R. and Rowley, P
Published: 2018
Publisher: UKERC
This briefing note summarises Great Britain’s local gas demand from the 2nd of April 2017 to the 6th of March 2018 and compares this to electrical supply. The data covers the UK cold weather event on the 1st March, providing insights into the scale of hourly energy flows through both networks.
A peak hourly local gas demand of 214 GW occurred at 6pm on the 1st of March, which compared to a peak electrical supply of 53 GW occurring at the same time.
The data highlights a critical challenge – managing the 3-hour difference in demand from 5am to 8am on the local gas network during the heating season. Whilst flexibility in the gas system is provided using a change in pressure to store extra energy in the network to meet increasing demand, the electrical system has no comparable intrinsic equivalent.
The findings add to previous work funded by UKERC on thermal energy storage , heat incumbency, and flexibility of electrical systems to provide insights into the decarbonisation of heat in Britain, helping to inform decision-making, modelling of future networks and highlighting key areas for future research and innovation.
A greater research and innovation focus to reduce the 5am-8am 3-hour difference in heat demand is necessary.
Author(s): McGlade, C., Ekins, P., Bradshaw, M. and Watson, J.
Published: 2015
Publisher: UKERC
A briefing paper Dr Christophe McGlade and Professor Paul Ekins, UCL Institute for Sustainable Resources and UCL Energy Institute, University College London; Professor Michael Bradshaw, Warwick Business School, University of Warwick; and Professor Jim Watson, UK Energy Research Centre.
The research on which this brief paper draws was carried out by the UK Energy Research Centre (UKERC). The views expressed are those of the authors, rather than of any institution to which they may be affiliated.
Two recently published reports (McGlade & Ekins (2015), McGladeet al.(2014)) examine possible futures for fossil fuels, with a particular focus on the bridging role that natural gas may be able to play during a transition to a global low-carbon energy system. A related report (Bradshawet al.2014) considers the UKs global gas c
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): 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): Barrett, J., Owen, A. and Taylor, P
Published: 2018
Publisher: UKERC
To recover the cost of energy policies which support the transition towards a low carbon energy system, levies are applied to household and business energy bills. This briefing note focuses on the levies applied to households.
Household energy policy costs
Energy policy costs are applied to household electricity and gas bills, equating to 132, or 13% of the average energy bill in 2016. This research highlights how low-income households are hit hardest by the current arrangements as the poorest households spend 10% of their income on heat and power in their homes, whereas the richest households only spend 3%, so any increase in prices hits the poor disproportionately.
Energy service demands in the UK
Household electricity and gas use represents only 12% of total final UK energy use. Total energy use includes all the energy used to provide househ
Author(s): Bradshaw, M.
Published: 2018
Publisher: Warwick Business School and UKERC
Natural gas plays a critical role in the UK’s energy system, providing twice as much energy as electricity, thus the secure and affordable supply of natural gas is an essential element of UK energy security and a key objective of Government policy. The starting proposition for this report is that Brexit is coming at a time when there are already major challenges to the UK’s future gas security.
This report deploys two aspects of previous UKERC research on UK gas security: first, a supply chain approach to assessing UK gas security; and second, a whole systems approach that places current and future gas demand within the context of the decarbonisation of the UK’s energy system. This is because there are key uncertainties in the wider system that have important implications for future gas demand. It is in this context that the Brexit decision has created additional uncertainty at a time when the UK energy sector needs to make critical investment decisions. In the current situation we can conceive of a ‘Brexit Interregnum’ whereby important decisions and policies are delayed because of the demands of the Brexit negotiations.
This report has three objectives:
Author(s): Bradshaw, M.
Published: 2018
Publisher: UKERC
The Midstream Infrastructure briefing considers the critical infrastructures - both hard and soft - that are necessary to link gas suppliers to end users. In many ways this is the most complex, least studied and most important part of the UK's gas supply chain. This briefing describes the various elements of the Midstream, assesses their current status, considers the potential impact on Brexit, and the challenges they pose in relation to future UK gas security.
The key challenge that the Midstream has to manage is the strong seasonality of UK gas demand, which is driven largely by winter demand for domestic heating. However, in recent years the growth of low-carbon generation (wind and solar) has introduced the additional complexity of intermittency, which is resulting in swings in gas demand on a much shorter time-frame. This is a challenge that is only going to increase in the future as coal-fired generation closes (by 2025) and intermittent low-carbon generation continues to grow.
Author(s): Bradshaw, M,
Published: 2018
Publisher: UKERC
The majority of studies of energy security focus on upstream security of supply. More recently, as the low-carbon transition has gathered momentum, there has been increasing interest in security of future demand as a challenge to the integrity of the gas supply chain.
This briefing is divided into five sections. The first section examines the current role of natural gas in the UK energy mix, as well as recent trends in power generation. The second section reports on recent research by UKERC on the future role of gas in the UK. The third section examines what National Grid’s (2017a) most recent Future Energy Scenarios have to say about the future role of gas. The fourth section reviews other industry analyses about the future role of gas. The fifth, and final section, examines the ways in which Brexit complicates the situation. The briefing concludes by highlighting the policy challenges in relation to future
Author(s): Bradshaw, M.
Published: 2017
Publisher: UKERC
This briefing reports the findings of the first UK Gas Security Forum, which brings together a range of stakeholders
from government, business, think-tanks and academia to consider the impact of Brexit on the UK gas industry. The aim of the Forum is to inform the Brexit negotiations and the formulation of a Post-Brexit UK Gas Security Strategy.
The Forum builds on previous research funded by UKERC on:The UKs Global Gas Challenge(Bradshaw et al. 2014) andThe Future Role of Natural Gas in the UK(McGlade et al. 2016). The approach adopted combines a supply chain analysis of energy security with a whole system approach, that places gas security within the wider context of the decarbonisation of the UK energy system. In keeping with the wider framing of UK energy policy within the energy trilemma, it is assumed that a future UK gas strategy must de
Author(s): Sorrell, S., Speirs, J., Bentley, R., Brandt, A. and Miller, R..
Published: 2009
Publisher: UKERC
The report also focuses on the broadly ‘physical’ factors that may restrict the rate at which conventional oil can be produced, including the production profile of individual fields and the distribution of resources between different sizes of field. While these are invariably mediated by economic, technical and political factors, the extent to which increased investment can overcome these physical constraints is contested. Global oil supply is also influenced by a much wider range of economic, political and geopolitical factors (e.g. resource nationalism) and several of these may pose a significant challenge to energy security, even in the absence of ‘below-ground’ constraints. What is disputed, however, is whether physical depletion is also likely to constrain global production in the near-term, even if economic and political conditions prove more favourable. In practice, these ‘above ground’ and ‘below ground’ risks are interdependent and difficult to separate. Nevertheless, this report focuses primarily on the latter since they are the focus of the peak oil debate.
The report does not investigate the potential consequences of supply shortages or the feasibility of different approaches to mitigating such shortages, although both are priorities for future research.
Author(s): Bradshaw. M. and Watson. J.
Published: 2013
Publisher: UKERC
This response is largely based on research carried out within the UKERC project: The Geopolitical Economy of Global Gas Security and Governance: Implications for the UK. It also draws on UKERC’s energy system modeling research which has explored the changes that are necessary to meet the UK’s climate change targets.
Author(s): Bell, K.
Published: 2019
Publisher: UKERC
The gas and electricity sectors feature many different actors that interact in different ways, through commercial arrangements and physical transfers of energy. The activities of the larger actors – generators, suppliers, gas shippers, and network owners and operators – are regulated through various licences.
There is then a raft of standards and codes that govern the interfaces between the actors and many of the characteristics of equipment that is connected to the networks. Most of these documents were established when the gas and electricity sectors were first liberalised in the late 1980s and early 1990s. Although a number have seen various revisions since then, many industry observers have argued that they are out of step with technological and market developments and difficult to change.
This document contains the UKERC response to the 2019 consulation by BEIS/Ofgem about how and why the codes might be revised.
Author(s): RCUK, NERC, ESRC and UKERC
Published: 2010
Publisher: UKERC
The west of Shetland region is physically a very different environment to the Gulf of Mexico, so environmental impact of a deep water spill in this area would be different, in many aspects.
A regulatory system could be enacted to compel companies to develop a shareddeep-water rapid response system to cap wells, and the levels of insurance cover companies are obliged to have could be increased.
The UKs regulatory system is robust but could be improved, though there is a limit to which increased regulation can be implemented and effective.
Scenarios which may reduce the need to exploit deepwater reserves during the transition to a low carbon economy are discussed. However, given our current reliance on oil and gas, such exploitation may be necessary.
Under free market regulations the contribution of deepwater reserves to security of supply may be limited, though there may be some economic benefits of exploitation
Author(s): Welsby, D.
Published: 2018
Publisher: UKERC
This UKERC working paper reviews the literature on modelling natural gas demand and supply. This includes modelling natural gas markets in isolation, and as part of its role in the wider energy system.
This review is part of the work on a new, global gas model at the Institute for Sustainable Resources at University College London, through a UKERC PhD Studentship. The focus of the new model is on global gas production and trade, and its coupling with the TIMES Integrated Assessment model at University College London (TIAM-UCL) to represent gas demand.
The main section of this working paper provides a review of existing methods which model both supply chain and demand dynamics of natural gas (Part 1: recoverable volumes and corresponding costs of natural gas; Part 2: wider energy-system models; Part 3: natural gas market models). As with any modelling, it was found that there is always a trade-off between necessary simplifications, and the uncertainties and complexities which surround energy-economic-environmental systems.
In Part 1, this paper reviews a range of studies that have estimated recoverable volumes of natural gas. This includes both deterministic (e.g. a single point estimates of natural gas) and stochastic (e.g. probabilistic estimates including ranges of uncertainty) modelling methods, and the strengths and limitations of the approaches employed. The overall conclusion is that some level of probabilistic assessment is required when estimating recoverable volumes of natural gas and the cost range of extraction, particularly given the huge uncertainties inherent in the development of these resources (techno-economic, geological, environmental).
A key contribution of this review, in Part 2, is how natural gas is represented in energy system and integrated assessment models. This represents how gas supply and demand dynamics are also driven by wider developments in energy and environmental systems. Standalone natural gas models, described in Part 3, include gas market complexities. These have more disaggregated time-slices/temporal horizons in order to capture seasonality and the interaction between market agents. However, there is a trade-off between the temporal disaggregation, and the overall scope of the model. In short, the decision to take gas consumption from TIAM-UCL yields the benefit of a whole systems approach in the long-run, whilst limiting seasonal disaggregation in the short-term.
In section III, the paper introduces a new natural gas production and trade model, which is linked to TIAM-UCL. This linkage includes an aggregation of supply cost curves from a field-level gas volume and cost database, into the regions in TIAM-UCL. The gas model is able to account for aspects of gas markets which TIAM-UCL does not have in its architecture; e.g. fiscal regimes, take-or-pay contracts, price indexation.
Given the proprietary nature of cost data for natural gas extraction, a linear regression model was used to assign supply costs (the capital and operating expenditures required to get the gas out of the ground) to gas fields where no public information was available. This gas model aims to provide insights by quantifying various parameters which determine supply costs for individual natural gas fields, both developed and undeveloped; these include water depths, reservoir depths, the levels of hydrogen sulphide or carbon dioxide, and assumed risks to investment (e.g. due to location, political conditions, etc.).
The combination of the two models is intended to model scenarios, providing new insights into future natural gas price formation mechanics and longer-term policy developments which could alter/influence supply and demand.
Author(s): Chaudry, M., Jenkins, N. and Strabc, G.
Published: 2007
Publisher: UKERC
A multi-time period combined gas and electricity network optimisation model was developed. The optimisation model takes into account the varying nature of gas flows, network support facilities such as gas storage and the power ramping characteristics of electricity generation units. The combined optimisation is performed from an economic viewpoint, minimising the costs associated with gas supplies, linepack management, gas storage operation, electricity generation and load shedding. It is demonstrated on two case studies, a simple example, and on the GB network.
Author(s): Bell, K., Gross, R. and Watson, J
Published: 2018
Publisher: UKERC
The RIIO (Revenue=Incentives+Innovation+Outputs) model, introduced in 2013, is designed to ensure that payments to companies running the gas and electricity transmission and distribution networks are fair to network users and permit the recovery of reasonable costs in developing, maintaining and operating the networks.
The network licensees allowed revenue is linked to their performance and should therefore offer them incentives for securing investment, driving innovation and delivering the service that customers expect. However, some commentators have suggested that the licensees have been making unjustified profits. With network charges making up around a quarter of the average household energy bill, it is anticipated that the new price control framework will be tougher and provide lower expected returns for networklicensees.
The RIIO-2 frameworkconsultation is welcome. Ofgems final view on price control allowances will be published by the end of 2020 with the new network price controls ('RIIO-2') due to be implemented in 2021.
General commentsIn our submission we respondedto the individual points raised in the call. We also note the following:
We support the proposal to reduce the price control period from 8 to 5 years. The energy system is undergoing unprecedented change, not only with continued transformation of the generation background but also major changes to the way electricity is used, such as for transport and heating. However, the rate and precise locations of these changes is uncertain. A shorter price control period will provide the opportunity for incentives and cost recovery to be adapted to the changing circumstances.
Maintenance of acceptable levels of reliability while facilitating the energy system transformation at least cost requires substantial innovation in technologies, business processes and commercial arrangements. The development of new innovations and associated benefits to consumers often takes years to be realised, sometimes beyond a price control period in which network company shareholders would expect a return. We therefore support the proposal to retain dedicated innovation funding but encourage greater clarity on the scope of activities that can make use of such funding and on best practice in the generation and dissemination of evidence on proposed innovations.
We welcome moves to increase the accountability of the network companies and would urge Ofgem to concentrate on those measures that have a genuine and positive impact on the network companies activities in the context of the whole energy system. We note that thisis not restricted to the business plans submitted under RIIO-2 but extends to a whole raft of codes and interactions. These include the evolving responsibilities of the Electricity System Operator (ESO), the relationships between the ESO, the transmission owners and the Distribution Network Operators, and the processes for ensuring that the full set of codes, standards and market arrangements are coherent and fit for purpose. This is a challenging task that requires constant attention to the big picture and sufficient resources, commitment and expertise on the part of the network owners, system operators and Ofgem.
In applying tighter controls that avoid excessive returns to the network licensees owners, the upside and downside risks should be clearly assessed and incentives for managing risk placed on those parties best placed to do so.
Author(s): Gross, R. and Bell. K.
Published: 2020
Publisher: UKERC
Pathways that are consistent with legislated net zero targets are likely to see highly significant changes to demand for electricity. When these changes will start to take place and how quickly is uncertain, which leads to challenges when setting price controls. Key elements to circumnavigate this will be flexibility and scenario planning.
The need for network reinforcement can be reduced by the appropriate use of flexibility, e.g. in the timing of EV charging. However, the means by which different sources of flexibility might be encouraged and then utilised are still immature and it is not yet clear which will actors prove to be the most significant and efficient in providing services.
Flexibility can only go so far in helping meet power supply needs; at some point, network capacity often proves the most cost-effective means, especially when considering its reliability and lifetime, and the opportunities provided by asset replacement. The triggering of investment in network assets presents an opportunity not just to meet the immediate need or that forecast for the next few years, but to provide for the maximum transfer that can be envisaged throughout the path to net zero. This is likely to be cheapest for consumers over the longer term as the incremental cost of additional electrical capacity is small relative to the total cost of aproject, it avoids the need for repeated interventions, andit saves on the long-term cost of network losses.
Ofgem has noted in the consultation document that some form of scenario planning of investment is likely to be needed. A number of scenarios should be developed that encompass key uncertainties but are consistent across Britain in respect of the whole, multi-vector system, and associated assumptions.
There should be engagement with Local Authorities and other stakeholders to develop regional plans of future energy needs, such as a Local Area Energy Plan. This engagement is important as local, regional, or devolved administration policies as well as different geographies and starting points can drive different actions.
Innovation is a long-term process and uncertainty is inherent to it there is always the potential for unforeseen things to arise. What this means for the energy system is that:
Where there is uncertainty about the effect or cost of new practices or technologies on an energy system and its users who ultimately pay but also benefit from innovations that are adopted it is reasonable for those users to share the risk by sharing the cost of resolution of the uncertainties. However, arguments might be made that costs should be shared not by energy system users, i.e. its customers, but by taxpayers, e.g. through funding by UKRI.
A less than perfect set of arrangements for the sharing of costs between different parties should be accepted if that is what is necessary to support R&D capacity, address risks, and drive innovation. Moreover, the amount of network customers money that is being proposed in RIIO-ED2 to support innovation is modest compared with the network companies total expenditure and the benefits that will accrue to customers and society as a whole in the energy system transition.
Good governance and good practice on the part of network licensees is essential to ensure that customers money is used effectively. In particular, we agree with Ofgem that data transparency associated with network innovation projectsneeds to be much improved.
In order that the scope of Network Innovation Allowance (NIA) funding is not set too narrowly, we think it important to have a clear understanding of what a successful energy system transition involves. We include in our response a first draft of a definition and include recommendations for the threshold that projects must meet to be funded.
Summary: The greatest challenges faced by Distribution Network Operators (DNOs) in forming investment plans relate to the gathering and use of information with suitable levels of spatial and temporal detail. Access to smart meter data should help, but innovation will be required to turn data into useful information.
A final observation is that it is important for the UKs economy as a whole that the UK has the capacity to undertake research and development, to innovate, and to generate evidence in order to drive the commercial viability of ideas
Author(s): Watson, J., Ekins, P., Gross, R., Froggatt, A., Barrett, J., Bell, K., Darby, S., Webb, J., Bradshaw, M., Anable, J., Brand, C., Pidgeon, N., Demski, C. and Evensen, D.,
Published: 2017
Publisher: UKERC
UKERCs 2017 Review of Energy Policy, appraises energy policy change over the last 12 months, and makes a series of recommendations to help meet the objectives of the governments Clean Growth Plan.
Our main recommendations are:
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., 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): 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): Froggatt, A., Wright, G. and Lockwood, M
Published: 2017
Publisher: Chatham House, the Royal Institute of International Affairs
• Negotiations over the terms of ‘Brexit’ are likely to be lengthy, complex and difficult. Energy is one policy area in which it may be easier for the UK and future EU27 to find common ground
• Energy cooperation over the past decades has helped European countries to enhance their geopolitical security, respond to growing climate threats, and create a competitive pan-European energy market. Maintaining close cooperation in this field, and the UK’s integration in the European internal energy market (IEM), will be important for the UK and the EU27 post-Brexit.
• Strong UK–EU27 energy cooperation could help ensure that existing and future interconnectors – physical pipes and cables that transfer energy across borders – between the UK, Ireland and the continent are used as efficiently as possible. As European economies, including the UK, look to decarbonize further, interconnectors will help minimize the costs of operating low-carbon electricity systems, and help lower electricity prices for UK consumers.
• The UK and the EU27 have identified the special relations between the UK and the Republic of Ireland as a priority for negotiations. Any future agreement needs to maintain the Single Electricity Market (SEM) across the island of Ireland, as failure to do so could result in an expensive duplication of infrastructure and governance.
• EU funds and European Investment Bank (EIB) loans account for around £2.5 billion of the UK’s energy-related infrastructure, climate change mitigation, and research and development (R&D) funding per year. Replacing these sources of finance will be necessary to ensure that the UK’s energy sector remains competitive and innovative.
• The UK intends to leave Euratom, the treaty which established the European Atomic Energy Community and which governs the EU’s nuclear industry. This process – dubbed ‘Brexatom’ – will have a significant impact on the functioning of the UK’s nuclear industry, particularly in respect to nuclear material safeguards, safety, supply, movement across borders and R&D. Achieving this within the two-year Brexit time frame will be extremely difficult. The UK will need to establish a framework that it can fall back on to ensure nuclear safety and security.
• Remaining fully integrated with the IEM would require the UK’s compliance with current and future EU energy market rules, as well with some EU environmental legislation. The UK government, British companies and other relevant stakeholders will need to maintain an active presence in Brussels and European energy forums, so that constructive and informed engagement can be sustained.
• Without a willingness to abide by the jurisdiction of the European Court of Justice (ECJ), and in the absence of a new joint UK–EU compliance mechanism, the UK may be required to leave the EU Emissions Trading System (ETS) – an instrument in the UK’s and EU’s fight against climate change. Leaving the ETS would be complicated, even more so if the UK leaves before the end of the ETS’s current phase (2013–20). To maintain carbon pricing in some form outside of the ETS, the UK would need to either establish its own emissions trading scheme, which would be complicated and time-consuming; or build on the carbon floor price and introduce a carbon tax. Either of these potential solutions would need political longevity to be effective.
• It is in both the UK’s and the EU27’s interests for the UK to continue to collaborate on energy policy with EU and non-EU member states. The best way to achieve this would be to establish a robust new pan-European energy partnership: an enlarged European Energy Union. In particular, such a partnership could offer a useful platform for aligning EU policies with those of third countries, including the UK, Norway and Switzerland, while allowing them to fully access the IEM and push forward common initiatives. Experience suggests that the EU27 would be more receptive to working within an existing framework or multilateral approach (as with the European Energy Community) than to adopting a bilateral approach (as the EU currently does in its energy relations with Switzerland).
Author(s): Watson, J., Ketsopoulou, I., Dodds, P., Chaudry, M., Tindemans, S., Woolf, M. and Strbac, G.
Published: 2018
Publisher: UKERC
Energy security is a central goal of energy policy in most countries and with rapid changes occurring throughout the UK energy sector, it remains high on the policy agenda. Recent concerns about UK gas supplies - highlighted by National Grid's gas deficit warning demonstrated just how fundamentally important it is to have a reliable energy system.
Using a number of indicators, ‘The Security of UK Energy Futures’ assesses aspects of security such as energy availability, reliability, sustainability and affordability to examine how energy security risks will change over time
The report draws three main conclusions:
Author(s): Bradshaw, M., Bridge. G., Bouzarovski, S., Watson, J. and Dutton, J.
Published: 2014
Publisher: UKERC
A UKERC Research Report exploring the UK's global gas challenge. This report takes an interdisciplinary perspective, which marries energy security insights from politics and international relations, with detailed empirical understanding from energy studies and perspectives from economic geography that emphasise the spatial distribution of actors, networks and resource flows that comprise the global gas industry.
Natural gas production in the UK peaked in 2000, and in 2004 it became a net importer. A decade later and the UK now imports about half of the natural gas that it consumes. The central thesis of the project on which this report is based is that as the UK’s gas import dependence has grown, it has effectively been ‘globalising’ its gas security; consequently UK consumers are increasingly exposed to events in global gas markets.
Author(s): McGlade. C., Pye. S., Watson. J., Bradshaw. M., Ekins. P.
Published: 2016
Publisher: UKERC
Author(s): Khalid, R. and Foulds, C.
Published: 2020
Publisher: UKERC
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): Breen, R.
Published: 2012
Publisher: UKERC
This UKERC Research Landscape provides an overview of the competencies and publicly funded activities in oil and gas 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: OIL AND GAS
Author(s): Miller, R.., Sorrell, S. and Speirs, J.
Published: 2009
Publisher: UKERC
The dispute between optimists and pessimists over the future of global oil supply is underpinned by equally polarised disagreements over a set of more technical issues. Given the complexity and multi-dimensional nature of this topic, the existence of such disagreements is unsurprising. However, the situation is made worse by the inadequacy of the publicly available data and the scope this creates for competing views and interpretations. Improved data on individual fields could go a long way towards resolving such disagreements, but this seems unlikely to become available in the foreseeable future. Nevertheless, there is potential for increasing the degree of consensus in a number of areas and some progress has already been made. This report looks in more detail at two of these issues, namely:
Author(s): Sorrell, S. and Speirs, J.
Published: 2009
Publisher: UKERC
The primary objective of this report is to describe and evaluate these different methods. Primary attention is paid to the methods based upon the extrapolation of historical trends, since these are widely used by the analysts concerned about global oil depletion. A second objective is to summarise and evaluate the estimates that have been produced for the global URR of conventional oil and to assess the implications for future oil production. Of particular interest is the relative plausibility of the optimistic and pessimistic estimates and the implications of both for medium-term oil supply.
Author(s): Brandt, A.
Published: 2009
Publisher: UKERC
This systematic review assesses the insight offered by thesemethodologies and critically evaluates their usefulness in projecting future oil production.It focuses on models that project future rates of oil production, and does not address themodeling or estimation of oil resources (e.g., ultimately recoverable resources, or URR).Models reviewed include the Hubbert methodology, other curve-fitting methods, simulations of resource discovery and extraction, detailed bottom-up models, and theoretical and empirical economic models of oil resource depletion. Important examples of published models are discussed, and the benefits and drawbacks of these models are outlined. I also discuss the physical and economic assumptions that serve as the basis for the studied models.
Author(s): Bentley, R., Miller, R.., Wheeler, S. and Boyle, G.
Published: 2009
Publisher: UKERC
The models that have been reviewed for this study are described below. As far as possible, the same format has been used to describe each model, to facilitate comparison. Each description commences with a list of the more common basic input and output parameters, assumptions, definitions, components and data sources, and a statement of the type of model. Where appropriate, a brief comment on the model is included at this stage.
Author(s): Bentley, R., Miller., R.., Wheeler, S. and Boyle, G.
Published: 2009
Publisher: UKERC
This report provides a detailed comparison and evaluation of fourteen contemporaryforecasts of global oil supply. The forecasts are based upon mathematical models ofvarious levels of complexity, embodying a wide range of modelling approaches andassumptions. In addition, the views of two oil companies on the likely adequacy of future oil supply are also summarised.
Author(s): Sorrell, S. and Speirs, J.
Published: 2009
Publisher: UKERC
This report summarises several of the significant issues associated with oil production and reserve data. A fuller understanding of these issues provides a necessary basis for an objective examination of global oil depletion. The report addresses the subject in four sections:
Author(s): Thompson. E., Sorrell, S. and Speirs, J.
Published: 2009
Publisher: UKERC
The major inconsistency between reserve definitions is the choice of either a deterministic or probabilistic methodology. Within the class of deterministic definitions, the terms proved, probable and possible are widely used, but the use of this language is not standardised. Various descriptive terms are used which have very subjective interpretations. Within the class of probabilistic definitions there is wide agreement that 90%, 50% and 10% probability levels are appropriate to specify when reporting reserve estimates. Where deterministic terms such as proved are specified in a way allowing retrospective evaluation of estimates, the actual use of the term may not match the corresponding probabilistic definition.
There is a large physical uncertainty in our estimate of the oil originally in place due to the impossibility of measuring physicaland geological characteristics of the reservoir sufficiently accurately. Further uncertainty is introduced in estimating how much is both technically feasible and economically viable to extract, and again when aggregating results for individual fields to large areas.
Probabilistic estimates are therefore the most appropriate, because the definitions themselves include an acknowledgement of uncertainty. Probabilistic definitions do not lessen the intrinsic physical uncertainty in making an estimate but they can eliminate the possibility of deliberate or accidental bias. Because probabilistic definitions allow retrospective evaluation of the accuracy of reserve estimates, errors in estimation can be identified. This level of accountability is not achievable with deterministic definitions.
Author(s): Thompson, E., Sorrell, S. and Speirs, J.
Published: 2009
Publisher: UKERC
The term reserve growth refers to the increase in the estimates of ultimately recoverable resources (URR) of known fields over time. Reserve growth has contributed significantly more to reserve additions than new discoveries over the past decade and is expected to continue to do so in the future. But despite the crucial importance of reserve growth for future global oil supply, it remains both controversial and poorly understood. There is a great deal of work to be done before reliable estimates of future reserve growth can be made. This entails both the collation of adequate and reliable fieldlevel data from which to extrapolate future reserve growth, and updating and refining the very rough and preliminary forecast made by the US Geological Survey (USGS), which remains the most comprehensive study to date. 'Unpacking' the definition of reserve growth down to its constituent elements reveals that there are a number of definitional issues still to be resolved, in particular regarding the definition of reserves themselves and what categories of oil should be included. For the purposes of estimating reserve growth, it must be clearly defined what categories of oil are considered as their growth characteristics may be different.
Author(s): Bradshaw, M.
Published: 2012
Publisher: UKERC
This submission focuses on the potential impact of shale gas production on the global gas industry. Firstly, it suggests that the rapid development of shale gas production in the United States (US) has had a significant impact as it has resulted in the loss of a major market for LNG exporters. Events in Japan post-Fukushima are also an important factor in explaining the current situation. Secondly, the very low price for gas in the US, as a result of shale gas production, is putting pressure on gas price formation, both in Europe in relation to long-term oil-indexed pipeline imports and in the Asia-Pacific region in relation to long-term oil-indexed LNG imports. However, the high-price of oil is also a key factor in the current debate over the future pricing of natural gas. To conclude, the potential for significant shale gas production is an important factor in the current uncertainty over the future of the global gas industry, but it is not the only factor at play and any assessment of shale gas must be made in the wider context of multiple uncertainties.
Author(s): McGlade, C., Speirs, J. and Sorrell, S.
Published: 2012
Publisher: UKERC
This response addresses the first two questions of the call for evidence on the impact of shale gas on energy markets: firstly what estimates exist for the amount of shale gas in place in the UK, Europe, and the rest of the world, and what proportion is recoverable; and secondly why estimates for shale gas are so changeable.
UKERC recently conducted a comprehensive review of 62 studies that provide original estimates of regional and global shale gas resources [1
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): Vorushylo, I., Ogunrin, S., Ghosh, R., Brandoni, C. and Hewitt, N.J.
Published: 2020
Publisher: UKERC
Steering Committee consisting of female representatives from key organisations in the NI heat sector, including the Department for the Economy, the Utility Regulator, a local renewable industry group (NIRIG), the transmission and distribution system operators (NI Electricity Networks and SONI), an energy charity (NEA Northern Ireland), the Consumer Council and a public affairs consultancy (Stratagem).
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