1 Renewable Energy for Transport Policy Report Lead author: Authoring team: Type: Robert Kunze (KIT), Jonathan Gomez (KIT), Dogan Keles (KIT) Thomas Haasz (USTUTT), Ulrich Fahl (USTUTT), David Fraboulet (KIC-IE), Louise Coffineau (KIC-IE), Paul Deane (UCC), Eamonn Mulholland (UCC) Policy Report (PR) Publication date: September 2016 26th January 2017, Brussels
2 Outline Background and Objectives Transport without Fossil Fuels Model-based Scenario Analysis Conclusions
3 Background Transport is vital to societies and economies Transport is a major contributor to GHG emissions Traffic emissions are the main cause of local air pollution Reduction in oil-based energy for transport is needed
4 Objective of the Policy Report Overview of the status quo of renewable energy in transport sector regarding EU targets Not covered in this presentation Analysis of pathways to reach the long-term targets Opportunities for transport without fossil fuels Scenario assumptions Model results TIMES PanEU and TE3
5 Transport without Fossil Fuels Non-motorised transport and public transport Small Individual Carriers (SICs) low-power electrified urban mobility, multimodality Synthetic fuel (BioFuel) and Combustion Engine no new major investments, but emissions Battery energy efficient, but lower range Hybridations Hydrogen Fuel Cell
6 Model-based Scenario Analysis Scenarios description Scenario ETS target (compared to 2005) GHG reduction target (compared to 1990) Share of renewable energy in (gross) electricity consumption Share of renewable energy in gross final energy consumption Transport policies (Low Commitment) (High Commitment) EU-28: -21 % (2020) -75 % (2050) EU-28: -21 % (2020) -43 % (2030) none EU-28: -30 % (2020) -80 % (2050) EU-28: -30 % (2020) -90 % (2050) EU-28: 30 % (2020) 45 % (2035) 60 % (2050) + Country specific objectives when available EU-28: 20 % (2020) 54 % (2050) none National targets for e-mobility and biofuel blending quotas Low Commitment () and High commitment () scenarios: Economy wide GHG reduction target starting in 2020, replacing the ETS in 2030 Cost minimization determines technology choices in TIMES PanEU
Final energy consumption [PJ] Base year 7 Final energy consumption of the transport sector in the EU-28 by transport mode from 2010 to 2050 16000 14000 12000 10000 8000 6000 4000 2000 0 Navigation Aviation Rail Truck Bus 3279 PJ 2168 PJ 2010 2020 2030 2040 2050 Individual motorized transport Until 2030 the sectoral scope of the GHG emission target hardly influences final energy consumption in the transport sector The largest savings in energy consumption in the High Commitment () scenario in 2050 are achieved through cars
8 Impact of GHG mitigation targets on key indicators in the transport sector Share of fuel cell vehicles in the truck and bus stock Share of fuel cell vehicles in the passanger car fleet Share of network (Hybrid-) electric vehicles in the truck and bus stock In 2030 the main GHG mitigation measures are biofuels and hybrid electric vehicles In 2050 PHEVs is the main GHG mitigation measure with biofuels only gaining importance in the Low Commitment () scenario 2030 Reduction of FEC of transport sector compared with 30% 25% 20% 15% 10% 5% 0% Share of network (Hybrid-) electric vehicles in the passanger car fleet Share of biofuels in FEC of transport sector Share of gas-based fuels (natural gas, LPG) in FEC of transport sector Share of other fossilbased fuels (GtL, CtL, Methanol, DME) in FEC of transport sector Share of fuel cell vehicles in the truck and bus stock Share of fuel cell vehicles in the passanger car fleet Share of network (Hybrid-) electric vehicles in the truck and bus stock 80% 60% 40% 20% 2050 Reduction of FEC of transport sector compared with 100% 0% Share of network (Hybrid-) electric vehicles in the passanger car fleet Share of biofuels in FEC of transport sector Share of gas-based fuels (natural gas, LPG) in FEC of transport sector Share of other fossilbased fuels (GtL, CtL, Methanol, DME) in FEC of transport
Number of vehicles [1000 veh] Base year 9 Car stock by energy carrier in the EU-28 from 2010 to 2050 by scenario 300000 250000 200000 150000 100000 50000 0 2010 2020 2030 2040 2050 Hydrogen FC hybrid Hydrogen FC Hydrogen IC Electricity Methanol FC Methanol IC Combined Combustion DME LPG Biodiesel Ethanol PHEV Ethanol hybrid Ethanol Natural Gas PHEV Natural Gas hybrid Natural Gas Gasoline PHEV Gasoline hybrid Gasoline Diesel PHEV Diesel hybrid If transport sector is subject to GHG mitigation targets, combustions engines are only applied as range extenders Large shares of full electric and fuel cell (FC) vehicles are only observed in the High Commitment () scenario Diesel
Million cars 10 Policy simulation for FR and DE with a focus on ethanol and plug-in hybrid electric cars France () Germany () France () Germany ()
Million cars 11 Policy simulation for FR and DE with a focus on ethanol and plug-in hybrid electric cars France () Germany () Comparison of the scenario to the scenario: Subsidy of 4.000 /car for PHEV from 2016 to 2018 Assumed increase in popularity of this technology afterwards PHEV substitut gasoline hybrids and conventional combustion engines France () Germany ()
12 Conclusions With state-of-the-art transport technologies, a significant reduction in oil demand and GHG emissions is possible
13 Conclusions With state-of-the-art transport technologies, a significant reduction in oil demand and GHG emissions is possible Electric propulsion is very promising, including hybrid systems and fuel cells
14 Conclusions With state-of-the-art transport technologies, a significant reduction in oil demand and GHG emissions is possible Electric propulsion is very promising, including hybrid systems and fuel cells France and Germany until 2030: Addressing CO 2 emission gaps, other GHG emissions and setting of post-2021 standards Recharging infrastructure as well as high taxation for conventional vehicles/fuels and economic incentives for alternative vehicles/fuels is necessary to trigger market effects
15 Conclusions With state-of-the-art transport technologies, a significant reduction in oil demand and GHG emissions is possible Electric propulsion is very promising, including hybrid systems and fuel cells France and Germany until 2030: Addressing CO 2 emission gaps, other GHG emissions and setting of post-2021 standards Recharging infrastructure as well as high taxation for conventional vehicles/fuels and economic incentives for alternative vehicles/fuels is necessary to trigger market effects EU-28 until 2050: Until 2030, transport shows the smallest sectoral contribution to GHG reduction With ambitious EU 2050 GHG targets, transport becomes of great importance By 2050, electric vehicles might reach a market share of over 90 % in the car stock
16 Outlook Uncertain development of fuel cell and battery prices requires regular monitoring The policy measures examined are to be understood as starting points Economic evaluation of impacts at the country level not investigated yet Analysis of optimal policy packages desirable
17 Selected References EC-related references: see the Policy Report for additional references [2009/28/EC] Directive 2009/28/EC of the European Parliament and of the Council of 23 April 2009 on the promotion of the use of energy from renewable sources and amending and subsequently repealing Directives 2001/77/EC and 2003/30/EC (Text with EEA relevance). In: Official Journal of the European Union L 140, 5.6.2009, p. 16-62. [2009/29/EC] Directive 2009/29/EC of the European Parliament and of the Council of 23 April 2009 amending Directive 2003/87/EC so as to improve and extend the greenhouse gas emission allowance trading scheme of the Community (Text with EEA relevance). In: Official Journal of the European Union L 140, 5.6.2009, p. 63 87. [2009/30/EC] Directive 2009/30/EC of the European Parliament and of the Council of 23 April 2009 amending Directive 98/70/EC as regards the specification of petrol, diesel and gas-oil and introducing a mechanism to monitor and reduce greenhouse gas emissions and amending Council Directive 1999/32/EC as regards the specification of fuel used by inland waterway vessels and repealing Directive 93/12/EEC (Text with EEA relevance). In: Official Journal of the European Union L 140, 5.6.2009, p. 88-113. [2014/94/EU] Directive 2014/94/EU of the European Parliament and of the Council of 22 October 2014 on the deployment of alternative fuels infrastructure (Text with EEA relevance). In: Official Journal of the European Union L 307, 28.10.2014, p. 1 20. [COM(2010)265] Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions: Analysis of options to move beyond 20% greenhouse gas emission reductions and assessing the risk of carbon leakage, Brussels 2010. [COM(2010)2020] Communication from the Commission: Europe 2020. A strategy for smart, sustainable and inclusive groth, Brussels 2010. [COM(2011)112] Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions: A Roadmap for moving to a competitive low carbon economy in 2050, Brussels 2011. [COM(2011)144] White Paper: Roadmap to a Single European Transport Area Towards a competitive and resource efficient transport system, Brussels 2011.
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Source: EIA (2016) 33 Source: EVI (2016) 2 Selected Variables TE3 Model 1,000 projected battery cost per kwh 1.5 750 dollar/litre 1 dollar/kwh 500 0.5 250 0 2000 2004 2008 2012 2016 2020 2024 2028 Time (Year) diesel price[us] : Data diesel price[us] : S1 E85 price[us] : Data E85 price[us] : S1 gasoline price[us] : Data gasoline price[us] : S1 0 2000 2004 2008 2012 2016 2020 2024 2028 Time (Year) projected battery cost per kwh[bev] : S1 - fuel cost + car ownership + + aggregate total car stock desired by industry income population + gap between desired and simulated - + aggregate total car stock + B "market dynamics loop" aggregate demand for new cars sales new car + new car sales by technology +