Transport electrification: A key element for energy system transformation and climate stabilization
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This paper analyzes the role of transport electrification in the broader context of energy system transformation and climate stabilization. As part of the EMF27 model inter-comparison exercise, we employ the MESSAGE integrated assessment modeling framework to conduct a systematic variation of availability, cost, and performance of particular energy supply technologies, thereby deriving implications for feasibility of climate stabilization goals and the associated costs of mitigation. In addition, we explore a wide range of assumptions regarding the potential degree of electrification of the transportation sector. These analyses allow us to (i) test the extent to which the feasible attainment of stringent climate policy targets depends on transport electrification, and (ii) assess the far-reaching impacts that transport electrification could have throughout the rest of the energy system. A detailed analysis of the transition to electricity within the transport sector is not conducted. Our results indicate that while a low-carbon transport system built upon conventional liquid-based fuel delivery infrastructures is destined to become increasingly reliant on biofuels and synthetic liquids, electrification opens up a door through which nuclear energy and non-biomass renewables can flow. The latter has important implications for mitigation costs.
- Anderson K, Bows A (2011) Beyond ‘dangerous’ climate change: Emission scenarios for a new world. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 369:20–44 CrossRef
- Azar C, Lindgren K, Larson E, Möllersten K (2006) Carbon capture and storage from fossil fuels and biomass—costs and potential role in stabilizing the atmosphere. Clim Chang 74:47–79 CrossRef
- Bosetti V, Longden T (2013) Light duty vehicle transportation and global climate policy: The importance of electric drive vehicles. Energy Policy 58:209–219 CrossRef
- Calvin K, Wise M, Klein D, McCollum D, Tavoni M, van der Zwaan B, van Vuuren D (2013) A multi-model analysis of the regional and sectoral roles of bioenergy in near-term and long-term carbon mitigation. Climate Change Economics.
- Cherp A, Adenikinju A, Goldthau A, Hughes L, Jansen J, Jewell J, Olshanskaya M, Soares de Oliveira R, Sovacool B, Vakulenko S (2012) Chapter 5—energy and security. Global energy assessment—toward a sustainable future, Cambridge University Press, Cambridge, UK and New York, NY, USA and the International Institute for Applied Systems Analysis, Laxenburg, Austria, pp. 325–384.
- Clarke L, Edmonds J, Krey V, Richels R, Rose S, Tavoni M (2009) International climate policy architectures: Overview of the EMF 22 International Scenarios. Energy Economics 31:S64–S81 CrossRef
- Edenhofer O, Knopf B, Barker T, Baumstark L, Bellevrat E, Chateau B, Criqui P, Isaac M, Kitous A, Kypreos S, Leimbach M, Lessmann K, Magne B, Scrieciu Å, Turton H, Van Vuuren DP (2010) The economics of low stabilization: Model comparison of mitigation strategies and costs. Energy Journal 31:11–48
- Edmonds J, Wilson T, Wise M, Weyant J (2006) Electrification of the economy and CO2 emissions mitigation. Environmental Economics and Policy Studies 7:175–203
- Grahn M, Azar C, Lindgren K, Berndes G, Gielen D (2007) Biomass for heat or as transportation fuel? A comparison between two model-based studies. Biomass Bioenergy 31:747–758 CrossRef
- Gül T, Kypreos S, Turton H, Barreto L (2009) An energy-economic scenario analysis of alternative fuels for personal transport using the Global Multi-regional MARKAL model (GMM). Energy 34:1423–1437 CrossRef
- Hedenus F, Karlsson S, Azar C, Sprei F (2010) Cost-effective energy carriers for transport—The role of the energy supply system in a carbon-constrained world. Int J Hydrog Energy 35:4638–4651 CrossRef
- IEA (2012) Energy technology perspectives 2012: Pathways to a clean energy system. International Energy Agency (IEA), Paris CrossRef
- Krey V, Riahi K (2009) Implications of delayed participation and technology failure for the feasibility, costs, and likelihood of staying below temperature targets—greenhouse gas mitigation scenarios for the 21st century. Energy Economics 31:S94–S106 CrossRef
- Kriegler E, Weyant JP, Blanford GJ, Krey V, Clarke L, Edmonds J, Fawcett A, Luderer G, Riahi K, Richels R, Rose SK, Tavoni M, van Vuuren DP (2013) The role of technology for achieving climate policy objectives: Overview of the EMF 27 study on global technology and climate policy strategies. Climatic Change. doi:10.1007/s10584-013-0953-7
- Kyle P, Kim SH (2011) Long-term implications of alternative light-duty vehicle technologies for global greenhouse gas emissions and primary energy demands. Energy Policy 39:3012–3024 CrossRef
- Luderer G, Bosetti V, Jakob M, Leimbach M, Steckel JC, Waisman H, Edenhofer O (2012) The economics of decarbonizing the energy system-results and insights from the RECIPE model intercomparison. Clim Chang 114:9–37 CrossRef
- McCollum DL, Krey V, Riahi K (2012) Beyond Rio: Sustainable energy scenarios for the 21st century. Natural Resources Forum.
- OECD/ITF (2012) Transport outlook 2012: Seamless transport for greener growth. International Transport Forum (ITF) of the Organisation for Economic Cooperation and Development (OECD), Paris
- Ogden J, Anderson L (eds.) (2011) Sustainable transportation energy pathways: A research summary for decision makers, The Regents of the University of California, Davis campus.
- Pacala S, Socolow R (2004) Stabilization wedges: Solving the climate problem for the next 50 years with current technologies. Science 305:968–972 CrossRef
- Riahi K, Dentener F, Gielen D, Grubler A, Jewell J, Klimont Z, Krey V, McCollum D, Pachauri S, Rao S, van Ruijven B, van Vuuren DP, Wilson C (2012) Chapter 17 - Energy Pathways for Sustainable Development. Global Energy Assessment—Toward a Sustainable Future, Cambridge University Press, Cambridge, UK and New York, NY, USA and the International Institute for Applied Systems Analysis, Laxenburg, Austria, pp. 1203–1306.
- Riahi K, Grübler A, Nakicenovic N (2007) Scenarios of long-term socio-economic and environmental development under climate stabilization. Technol Forecast Soc Chang 74:887–935 CrossRef
- Rogelj J, McCollum DL, O’Neill BC, Riahi K (2013) 2020 emissions levels required to limit warming to below 2 C. Nat Clim Chang 3:405–412 CrossRef
- Rose S, Kriegler E, Popp A (2013) Bioenergy in energy transformation and climate management. Climatic Change. doi:10.1007/s10584-013-0965-3
- Skinner I, van Essen H, Smokers R, Hill N (2010) Towards the decarbonisation of EU’s transport sector by 2050. Final report produced under the contract ENV.C.3/SER/2008/0053 between European Commission Directorate-General Environment and AEA Technology plc; see www.eutransportghg2050.eu.
- Sugiyama M (2012) Climate change mitigation and electrification. Energy Policy 44:464–468 CrossRef
- Tavoni M, Tol R (2010) Counting only the hits? The risk of underestimating the costs of stringent climate policy. Clim Chang 100:769–778 CrossRef
- Teske S, Pregger T, Simon S, Naegler T, O’Sullivan M, Schmid S, Pagenkopf J, Frieske B, Graus W, Kermeli K, Zittel W, Rutovitz J, Harris S, Ackermann T, Ruwahata R, Martensen N (2012) Energy [R]evolution: A sustainable world energy outlook, 4th ed. Greenpeace international, European Renewable Energy Council (EREC), Global Wind Energy Council (GWEC)
- Turton H (2006) Sustainable global automobile transport in the 21st century: An integrated scenario analysis. Technol Forecast Soc Chang 73:607–629 CrossRef
- van Vliet O, Krey V, McCollum D, Pachauri S, Nagai Y, Rao S, Riahi K (2012) Synergies in the Asian energy system: Climate change, energy security, energy access and air pollution. Energy Economics.
- van Vuuren D, den Elzen M, Lucas P, Eickhout B, Strengers B, van Ruijven B, Wonink S, van Houdt R (2007) Stabilizing greenhouse gas concentrations at low levels: An assessment of reduction strategies and costs. Clim Chang 81:119–159 CrossRef
- WBCSD (2004) Mobility 2030: Meeting the challenges to sustainability. World business council for sustainable development.
- Williams JH, DeBenedictis A, Ghanadan R, Mahone A, Moore J, Morrow WR, Price S, Torn MS (2012) The technology path to deep greenhouse gas emissions cuts by 2050: The pivotal role of electricity. Science 335:53–59 CrossRef
- Yang C, Ogden J, Sperling D, Hwang R (2011) California’s energy future: Transportation energy Use in California. California council on science and technology.
- Transport electrification: A key element for energy system transformation and climate stabilization
Volume 123, Issue 3-4 , pp 651-664
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