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Cost-effectiveness of alternative powertrains for reduced energy use and CO2 emissions in passenger vehicles

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  • Bishop, Justin D.K.
  • Martin, Niall P.D.
  • Boies, Adam M.

Abstract

This work analysed the cost-effectiveness of avoiding carbon dioxide (CO2) emissions using advanced internal combustion engines, hybrids, plug-in hybrids, fuel cell vehicles and electric vehicles across the nine UK passenger vehicles segments. Across all vehicle types and powertrain groups, minimum installed motive power was dependent most on the time to accelerate from zero to 96.6km/h (60mph). Hybridising the powertrain reduced the difference in energy use between vehicles with slow (tz-60>8s) and fast acceleration (tz-60<8s) times. The cost premium associated with advanced powertrains was dependent most on the powertrain chosen, rather than the performance required. Improving non-powertrain components reduced vehicle road load and allowed total motive capacity to decrease by 17%, energy use by 11%, manufacturing cost premiums by 13% and CO2 emissions abatement costs by 15%. All vehicles with advanced internal combustion engines, most hybrid and plug-in hybrid powertrains reduced net CO2 emissions and had lower lifetime operating costs than the respective segment reference vehicle. Most powertrains using fuel cells and all electric vehicles had positive CO2 emissions abatement costs. However, only vehicles using advanced internal combustion engines and parallel hybrid vehicles may be attractive to consumers by the fuel savings offsetting increases in vehicle cost within two years. This work demonstrates that fuel savings are possible relative to today’s fleet, but indicates that the most cost-effective way of reducing fuel consumption and CO2 emissions is by advanced combustion technologies and hybridisation with a parallel topology.

Suggested Citation

  • Bishop, Justin D.K. & Martin, Niall P.D. & Boies, Adam M., 2014. "Cost-effectiveness of alternative powertrains for reduced energy use and CO2 emissions in passenger vehicles," Applied Energy, Elsevier, vol. 124(C), pages 44-61.
    • Handle: RePEc:eee:appene:v:124:y:2014:i:c:p:44-61
    DOI: 10.1016/j.apenergy.2014.02.019
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    References listed on IDEAS

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    1. Meyer, I. & Wessely, S., 2009. "Fuel efficiency of the Austrian passenger vehicle fleet--Analysis of trends in the technological profile and related impacts on CO2 emissions," Energy Policy, Elsevier, vol. 37(10), pages 3779-3789, October.
    2. Ichinohe, Masayuki & Endo, Eiichi, 2006. "Analysis of the vehicle mix in the passenger-car sector in Japan for CO2 emissions reduction by a MARKAL model," Applied Energy, Elsevier, vol. 83(10), pages 1047-1061, October.
    3. Pasaoglu, Guzay & Honselaar, Michel & Thiel, Christian, 2012. "Potential vehicle fleet CO2 reductions and cost implications for various vehicle technology deployment scenarios in Europe," Energy Policy, Elsevier, vol. 40(C), pages 404-421.
    4. Kok, Robert & Annema, Jan Anne & van Wee, Bert, 2011. "Cost-effectiveness of greenhouse gas mitigation in transport: A review of methodological approaches and their impact," Energy Policy, Elsevier, vol. 39(12), pages 7776-7793.
    5. Greene, David L. & Plotkin, Steven E., 2001. "Energy futures for the US transport sector," Energy Policy, Elsevier, vol. 29(14), pages 1255-1270, November.
    6. Kloess, Maximilian & Müller, Andreas, 2011. "Simulating the impact of policy, energy prices and technological progress on the passenger car fleet in Austria--A model based analysis 2010-2050," Energy Policy, Elsevier, vol. 39(9), pages 5045-5062, September.
    7. Rogozhin, Alex & Gallaher, Michael & Helfand, Gloria & McManus, Walter, 2010. "Using indirect cost multipliers to estimate the total cost of adding new technology in the automobile industry," International Journal of Production Economics, Elsevier, vol. 124(2), pages 360-368, April.
    8. Thiel, Christian & Perujo, Adolfo & Mercier, Arnaud, 2010. "Cost and CO2 aspects of future vehicle options in Europe under new energy policy scenarios," Energy Policy, Elsevier, vol. 38(11), pages 7142-7151, November.
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    24. Choi, Hyunhong & Shin, Jungwoo & Woo, JongRoul, 2018. "Effect of electricity generation mix on battery electric vehicle adoption and its environmental impact," Energy Policy, Elsevier, vol. 121(C), pages 13-24.

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