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Demand and supply considerations for bioenergy penetration in the UK Using a MARKAL model and a Market Segment Analysis www.tsec-biosys.ac.uk Sophie Jablonski Imperial Centre for Energy Policy and Technology (ICEPT). Biomass role in the UK energy futures
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Demand and supply considerations for bioenergy penetration in the UKUsing a MARKAL model and a Market Segment Analysis www.tsec-biosys.ac.uk Sophie Jablonski Imperial Centre for Energy Policy and Technology (ICEPT) Biomass role in the UK energy futures The Royal Society, London: 28th & 29th July 2009
Overall Objectives • Explore the possible long-term contribution of bioenergy to the UK energy system • Design and apply a systematic framework with expert input to assess the potential UK bioenergy demand • Formulate different scenarios and analyse corresponding bioenergy penetration • Relate scenarios to evolving policy context
A systematic approach to assess UK bioenergy supply & demand DEMAND CONSTRAINTS FOR BIOENERGY IN THE UK • Market segment analysis / modelling • Formulation of hypotheses on bioenergy levels of market penetration QUALITATIVE INSIGHTS FOR SCENARIOS • Narratives problem structuring • Development of storylines SUPPLY CONSTRAINTS FOR BIOENERGY IN THE UK • Supply chain modelling / analysis(including spatial, sustainability analysis) • Technology modelling • Resource assessment modelling FORMULATION OF TSEC-BIOSYS BIOENERGY SCENARIOS QUANTITATIVE INSIGHTS FOR SCENARIOS • BIOSYS-MARKAL modelling runs and results ENVIRONMENTAL AND SUSTAINABILITY CONSTRAINTS FOR BIOENERGY IN THE UK • Environmental sustainability • Greenhouse gas balances • Stakeholders engagement
X Market segment analysis BIOENERGY MARKET SEGMENTATION (1) Segmentation of the market based on various geographic and non-geographic characteristics (called “segmenting dimensions”) … • IDENTIFICATION OF KEY FACTORS (2) • Identification of the key factors which can affect (positively or negatively) the uptake of bioenergy technologies at the project level, for example (heat sector): • Technical factors • Economical factors • Organisational factors(environmental, social, behavioural, etc.) Y … 1. Technical potential 2. Economic potential 3. Implementation potential
Specific objectives: MARKAL modelling • Explore the prospects for bioenergy in the UK energy system in the long-term, and how this is affected by sustainable energy policy objectives • Improve the modelling of bioenergy technologies and pathways in an energy systems model (UK-MARKAL) • Provide better quantitative insights • No UK energy systems model has undertaken a detailed analysis of the contribution of bioenergy pathways • In particular within integrated scenarios of low carbon and energy security policy objectives.
Constructing the BIOSYS-MARKAL model • Includes changes in structure of bioenergy module • Some added technologies / paths (e.g. pelletisation, heat technologies, aviation bio-kerosene) • Some neglected pathways(e.g. algal oil, dark fermentation, gas vehicles) • Detailed data review for all bioenergy technologies • Datasets update to reflect expert-informed, up-to-date, UK-specificbioenergy knowledge and expectations
Modelled scenarios BIOSYS1-4: overview High UK energy system independence(reliability / security) “Energyindependence above all” BIOSYS 2 “Environmentally consciousenergy autonomy” BIOSYS 3 Low environment / sustainability ambition High environment / sustainability ambition “World Markets”Markal Base Case BIOSYS 1 “Global sustainability” BIOSYS 4 Low UK energy system independence(reliability / security)
BIOSYS1->4 bioenergy resources 2 3 1 4
BIOSYS1->4 bioenergy final uses 2 3 1 4
Linking resources to end-uses • Use of wood biomass to heat is the most dominant pathway (esp. in BIOSYS 1 & 2) • Use of grass biomass significant to produce industrial heat and / or 2nd gen biofuels • Wet biomass to energy via AD biogas also important for power (& heat) production and /or injection into the natural gas grid (mostly in 3) • Some pathways of “refined” (imported) liquid biomass to energy play a role (bio-oil, bio-ethanol, bio-diesel) • Other important non-bioenergy pathways • In BIOSYS 1 & 2: Coal to power; natural gas to heat (<MT); oil to transport; no nuclear >MT • In BIOSYS 3 & 4: renewable to power + nuclear; decarbonised power to all end uses > MT
Bio-heat contribution • Bio-heat contribution is higher for BIOSYS scenarios than in other studies (MT / LT) – has the bio-heat role been overlooked? • RES mentions 2% heat from biogas and 6% from solid biomass in 2020 – only in line with BIOSYS 1 (9%) • No studies looked at bio-heat pathways for LT in details – BIOSYS contribution very high (30-50% except for 3) • Underpinning bio-heat penetration are very large increases in biomass resources – bioenergy farming stimulation, logistics & infrastructure are key • Domestic bioenergy crops production appears cost effective in modelled conditions (esp. in 2) BUT actual land uptake likely to be limited by (inter alia) farmers perceptions and competitions from other markets • Large imports of woodchips and pellets in BIOSYS 3 & 4 – to accommodate and transport to final uses
Bio-heat contribution (2) • Role of wet biomass / biogas injection in the gas grid only up to 1% of heat mix by 2020 – planning and expectations over this pathway need careful consideration • Most significant role for the service and industrial heat sectors – for low carbon futures • Influence of the natural gas grid assets’ “lifetime” important determinant of the actual biogas heat role • Balance between bio-heat in different sectors (residential, industrial, service) significantly variable – support in all sectors needed • High deployment of residential bio-heat affected by demand constraints (space availability, organisational capability etc.) • Policy objectives balance the use of bio-heat in different sectors
Bio-fuels (for transport) contribution • Contribution of bio-fuels to transport largely stimulated by RTFO (in line with other studies) – bio-fuels costly to produce and supply • In BIOSYS 3 become LT cost effective low carbon option in competition with electricity • Imported bio-fuels appear the most cost effective resource for such pathway – ST/MT availability key limitation • Domestic processing of bio-fuels (notably 2nd generation) needed in the MT – technology development status could be a bottleneck • Could imply a larger role for 1st generation bio-fuels, at least in the ST & MT
Bio-electricity contribution • Lower role (esp. co-firing) than suggested in comparative modelling exercises & studies – lifetime cost-effectiveness of bio-electricity lower than alternative pathways (notably renewables) • The possibility to use multi-fuels could enhance actual potential • Logistical advantages not modelled as economic drivers • Policy instruments (e.g. ROCs) could change the game • Developing a portfolio of low carbon options could include biomass beyond cost effectiveness
Main messages: MARKAL • New BIOSYS-MARKAL model used to run four scenarios constructed along the pillars of UK energy policy objectives • Results analysed in terms of bioenergy resources use and bioenergy pathways penetration in different end use sectors (heat, electricity and transport fuel) • Findings suggest that the complexity of different bioenergy pathways may have been overlooked in previous modelling exercises • A range of bioenergy pathways - notably bio-heat and bio-fuels for transport - may have a much wider potential role to play • The extent to which this potential is fulfilled will be further determined by resources availability, market segment constraints, and policy measures to improve deployment
Looking in more details: Market Segment Analysis (residential heat sector)
Specific objectives: Market Segment Analysis • Estimate the potential demand for bio-heat at present • Assess its short- to medium- term potential (2020) • Formulation of explorative scenarios (“hypotheses”)
Key factors of bioenergy uptake . NB: Detailed list of key factors and their descriptions can be found in the project’s publications
Qualitative assessment • Matrix • Assumptions; Summary • Most attractive branches • Medium to large scale installations managed by district heating companies (esp. cogeneration units can get financial incentive based on trading schemes and obligations • BUT barrier posed by space availability and incumbent fuel infrastructure
Biomass against Natural gas Quantitative assessment • Snapshot of competitiveness of bioenergy • Profitability index (PI) • Fossil fuel / biomass combinations • Sensitivity to changes in key parameters • Bio-heat can be profitable against fossil fuel heat in some market segments • Smaller scale investments less profitable: limited leverage from lower operating costs • Intervention of 1/3 party (notably in district heating) makes bio-heat less attractive-heat less attractive • Investments w. lower-costs biomass fuels (e.g. straw bales, or wood chips) more profitable than w. refined fuel (e.g. pellets) • Natural gas the hardest contender • Present policy incentives benefit bio-heat in larger scale CHP plants Biomass against Heating Oil
Hypotheses on residential bio-heat potential • Three different scenarios, i.e. conservative, the middle and the optimistic • Penetration varies between 1.5% and 20% of residential heat market • Overall (residential) bio-heat potential of the UK appears low. • Combination of high barriersfrom the technical point of view and a ratherunattractive economicpicture • Influence of the residential heat market’s present structure (ltd larger heat-only & CHP or DH)
Main messages: bio-heat MSA • Not all demand segments react the same way to a given policy and economic environment • Biomass is already cost competitive in some market segments but… there are important barriers to biomass technologies adoption which are non-economic • Log / pellets boilers are the technologies which can penetrate the residential / service market in the short term • The residential bio-heat market exhibits low levels of growth, with the bulk of the market in the next decades remaining mainly a “retrofit” one, and very few “new installations” built • ST/MT bio-heat potential strongly influenced by the present market structure (including the relative size of different branches) • The results of our assessment suggest an extremely fragmented market • (Privately owned and managed) micro- & small-scale individual installations represent >90% of the residential market • It is likely the situation will stay this way unless major changes happen
Linkage MSA & MARKAL • MSA -> MARKAL • Understanding non-economic key factors (modelling of penetration constraints) for the short to medium term • Modelling of the economics at the segment level (and of the detailed incentives) • Refining the model structure (technology availability, characterisation, chains hierarchy etc.) • MARKAL -> MSA • Competition between different energy sectors • Testing of “energy system”-wide policies • Understanding implications of penetration levels (modelling of supply constraints) • Long-term horizon (modelling tool to 2050)
Thank you for your attention! www.tsec-biosys.ac.uk