Energy system modelling in an uncertain world

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1 Energy system modelling in an uncertain world Manchester University Summer School 07/6/2016 Adam Thirkill 2015 Energy Technologies Institute LLP The information in this document is the property of Energy Technologies Institute LLP and may not be copied or communicated to a third party, or used for any purpose other than that for which it is supplied without the express written consent of Energy Technologies Institute LLP This information Energy is given Technologies in good faith based Institute upon the latest LLP information - Subject available to to notes Energy on Technologies page 1Institute LLP, no warranty or representation is given concerning such information, which must not be taken as establishing any contractual or other commitment binding upon Energy Technologies Institute LLP or any of its subsidiary or associated companies.

2 What is the ETI? ETI members The Energy Technologies Institute (ETI) is a public-private partnership between global industries and UK Government Delivering... Targeted development and demonstration of new technologies Shared risk System level strategic planning ETI programme associate See for more details on our projects 2.

3 The ETI works with: 25.

4 Why do energy system modelling? Energy systems are complex and inter-dependent, made more so by emissions reduction objectives: Efforts to cut emissions are substitutable across power, heat, transport, industry and infrastructure There are key decision points and choices are long lived Energy governed by well-understood physical laws, so quantitative modelling is capable of representing system interactions and capturing dynamics that would otherwise not be understood Types of Debate that ESME is used to inform What might be no regret technology choices and pathways to 2050? What is the total system cost of meeting the energy targets? What are the opportunity costs of individual technologies? What are the key constraints? e.g. resources, supply chains etc. How does uncertainty influence system design choices?

5 Knowledge from across ETI programme areas is integrated in ESME

6 ESME in use by the ETI, its members and partners ESME developed to inform technology development choices and targets for ETI & members ESME used to inform policy work by DECC* and CCC + on a range of issues ETI Members are developing own versions for specific countries of interest Academic research projects ongoing. Licences to use ESME for academic research are available. * UK Government Department of Energy & Climate Change + Committee on Climate Change, a statutory UK body

7 The ESME model and approach

8 The ESME modelling approach Least cost optimisation, policy neutral Deployment & utilisation of >250 technologies Probabilistic treatment of key uncertainties Pathway and supply chain constraints to 2050 Spatial and temporal resolution sufficient for system engineering

9 The resulting mathematical optimisation Decision variables: Deployment: per technology, per decade, per region Operation: per technology, per decade, per region, per timeslice Constraints: Mass balances and operational constraints Meet demand Meet CO 2 emissions targets Limits on rate of deployment Security of supply constraints A typical ESME optimisation has ~200,000 variables & constraints Feasible space for a 3d Linear Program Path followed by Simplex algorithm In ESME the optimisation is formulated as a Linear Program: All constraints are strictly linear All variables are continuous... a key approximation In matrix / vector notation: minimise f(x) = c t x such that Ax b and x 0

10 Typical ESME Outputs

11 Energy System Sankey Diagram A Typical 2050 Case Solar Hydro Tidal Stream Wave Wind Recoverable Heat Network Hot Water Electricity Nuclear Geothermal Heat Hydrogen Biomass Biomass Imports Biofuel Imports Liquid Fuel Dry Waste Wet Waste Gas Coal

12 ESME uncertainty analysis Examples of the assumptions used in ESME which are highly uncertain 1. Technology costs e.g. CCS power stations, Hydrogen Cars Cost improvement for novel technologies, efficiency improvements, safety, Fuel prices e.g. gas price, oil price, imported biomass price International supplies, demand from other countries, shale gas, Maximum UK resource for Biomass Sustainability questions, public acceptance, farmer acceptance, yields,...

13 ESME uncertainty analysis ESME is a Monte Carlo model Ranges and probability distributions on uncertain inputs Results are an ensemble of least-cost energy systems /kw Energy System Blueprints /kwh This effectively automates a large amount of sensitivity analysis

14 Electricity Generation Capacity Average case GW (Historic) Data 2014DC / Optimiser v

15 Spread of ESME results for 2050 power capacity GW

16 Space heating results from ESME Average case 450 Space Heat Production TWh Ground Source Heat Pump Air Source Heat Pump Electric Resistive Biomass Boiler Gas Boiler Oil Boiler District Heating (detached) District Heating (semi-det. & terraced) District Heating (flats & apartments) District Heating (commercial & public) (Historic)

17 Heat / Electricity (GW) Heat demand variability in 2010 UK system has to cope with 6x heat demand swing Existing gas distribution grid supports this Heat Electricity Design point for a GB heat delivery system Jan 10 Apr 10 July 10 Oct 10 Design point for a GB electricity delivery system GB 2010 heat and electricity hourly demand variability - commercial & domestic buildings R. Sansom, Imperial College

18 ESME space heating results: typical vs peak GW 350 Peak demand day Typical summer day Typical winter day Ground Source Heat Pump Air Source Heat Pump Gas Boiler Electric Resistive District Heating (detached) District Heating (semi-det. & terraced) District Heating (flats & apartments) District Heating (commercial & public) Storage (water tank) 0-50

19 Sensitivity analysis Monte Carlo results no-regret options, marginal choices 3 future UK demand cases alternative socio-economic pathways for the UK Long list of No technology X sensitivities opportunity cost metric Sensitivity to different CO 2 targets Sensitivity to improved/accelerated technology development Testing with more detailed tools Dispatch of the ESME electricity system is studied in PLEXOS More detailed buildings & heat optimisation More detailed peak day optimisation

20 Technology deployment CCS appears a mainstay, offshore wind more variable CCS (Mt in 2050) Offshore Wind (GW in 2050) Reference Case No new nuclear No Biomass No CCS 0 Reference Case No new nuclear No Biomass No CCS

21 Technology deployment CCS appears a mainstay, offshore wind more variable CCS (Mt in 2050) Offshore Wind (GW in 2050) Increasing investment in transmission grid and backup power stations Overall annual utilisation of power stations drops from 60% to 40% 0 Reference Case No new nuclear No Biomass No CCS 0 Reference Case No new nuclear No Biomass No CCS

22 Using opportunity cost to measure role of a technology in the system Opportunity cost of technology X is defined by two alternative scenarios: A. The least-cost energy system design using standard assumptions B. The least-cost energy system design if technology X unavailable Opportunity cost = Total Cost (B) Total Cost (A) = 0 if technology X is not present in the reference case (System A) > 0 if technology X is present in System A. Magnitude of the opportunity cost depends on the relationship between System A and System B: substitution or reconfiguration

23 Mt CO2/year CCS and Biomass consistently have the highest opportunity costs 600 Net CO2 Emissions (Historic) International Aviation & Shipping Transport Sector Buildings Sector Power Sector Industry Sector Biogenic credits Process & other CO2

24 CCS is high value as it creates options application of the same infrastructure for power, industry, enabling bioenergy usage and H2 production ETI energy system modelling points to energy system-wide value of CCS extending beyond low carbon electricity generation Low carbon electricity from fossil fuels (DECC Demos) CCS with biomass (Drax programme) Gasification applications (ETI demos) CCS on industrial emissions (to follow) Negative emissions Flexible low carbon fuels (hydrogen, syngas) Enables continued use of fossil fuels where very expensive to replace Low carbon energy diversity, portfolio of flexible low carbon energy vectors, option value & robustness in meeting carbon targets

25 ETI Scenarios UK energy system power, heating, transport, industry & infrastructure Bound by Climate Change Act 80% emissions reduction by 2050 Building on several years of modelling, analysis and scenario development using ESME Devised in consultation with ETI members and stakeholders Launched March 2015

26 ETI Scenarios

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29 Key Messages

30 Registered Office Energy Technologies Institute Holywell Building Holywell Park Loughborough LE11 3UZ For all general enquiries telephone the ETI on For more information about the ETI visit For the latest ETI news and announcements The ETI can also be followed on