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How carbon pricing changes the relative competitiveness of low-carbon baseload generating technologies

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  • Nicholson, Martin
  • Biegler, Tom
  • Brook, Barry W.

Abstract

There is wide public debate about which electricity generating technologies will best be suited to reduce greenhouse gas emissions (GHG). Sometimes this debate ignores real-world practicalities and leads to over-optimistic conclusions. Here we define and apply a set of fit-for-service criteria to identify technologies capable of supplying baseload electricity and reducing GHGs by amounts and within the timescale set by the Intergovernmental Panel on Climate Change (IPCC). Only five current technologies meet these criteria: coal (both pulverised fuel and integrated gasification combined cycle) with carbon capture and storage (CCS); combined cycle gas turbine with CCS; Generation III nuclear fission; and solar thermal backed by heat storage and gas turbines. To compare costs and performance, we undertook a meta-review of authoritative peer-reviewed studies of levelised cost of electricity (LCOE) and life-cycle GHG emissions for these technologies. Future baseload electricity technology selection will be influenced by the total cost of technology substitution, including carbon pricing, which is synergistically related to both LCOE and emissions. Nuclear energy is the cheapest option and best able to meet the IPCC timetable for GHG abatement. Solar thermal is the most expensive, while CCS will require rapid major advances in technology to meet that timetable.

Suggested Citation

  • Nicholson, Martin & Biegler, Tom & Brook, Barry W., 2011. "How carbon pricing changes the relative competitiveness of low-carbon baseload generating technologies," Energy, Elsevier, vol. 36(1), pages 305-313.
    • Handle: RePEc:eee:energy:v:36:y:2011:i:1:p:305-313
    DOI: 10.1016/j.energy.2010.10.039
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    12. Tran, Thomas T.D. & Smith, Amanda D., 2018. "Incorporating performance-based global sensitivity and uncertainty analysis into LCOE calculations for emerging renewable energy technologies," Applied Energy, Elsevier, vol. 216(C), pages 157-171.
    13. Miguel Pérez de Arce and Enzo Sauma, 2016. "Comparison of Incentive Policies for Renewable Energy in an Oligopolistic Market with Price-Responsive Demand," The Energy Journal, International Association for Energy Economics, vol. 0(Number 3).
    14. Chang-Jing Ji & Xiao-Yi Li & Yu-Jie Hu & Xiang-Yu Wang & Bao-Jun Tang, 2019. "Research on carbon price in emissions trading scheme: a bibliometric analysis," Natural Hazards: Journal of the International Society for the Prevention and Mitigation of Natural Hazards, Springer;International Society for the Prevention and Mitigation of Natural Hazards, vol. 99(3), pages 1381-1396, December.
    15. Dahlke, Steven, 2019. "Short run effects of carbon policy on U.S. electricity markets," SocArXiv b79yu, Center for Open Science.
    16. Motavasseli, Ali, 2016. "Essays in environmental policy and household economics," Other publications TiSEM b32e287e-169b-4e89-9878-1, Tilburg University, School of Economics and Management.
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    20. Zhou, Kaile & Yang, Shanlin & Shao, Zhen, 2016. "Energy Internet: The business perspective," Applied Energy, Elsevier, vol. 178(C), pages 212-222.
    21. Graham Palmer, 2012. "Does Energy Efficiency Reduce Emissions and Peak Demand? A Case Study of 50 Years of Space Heating in Melbourne," Sustainability, MDPI, vol. 4(7), pages 1-36, July.
    22. Steve Dahlke, 2019. "Short Run Effects of Carbon Policy on U.S. Electricity Markets," Energies, MDPI, vol. 12(11), pages 1-21, June.
    23. Barry W. Brook & Tom Blees & Tom M. L. Wigley & Sanghyun Hong, 2018. "Silver Buckshot or Bullet: Is a Future “Energy Mix” Necessary?," Sustainability, MDPI, vol. 10(2), pages 1-14, January.
    24. Zhang, Jianyun & Zhou, Zhe & Ma, Linwei & Li, Zheng & Ni, Weidou, 2013. "Efficiency of wet feed IGCC (integrated gasification combined cycle) systems with coal–water slurry preheating vaporization technology," Energy, Elsevier, vol. 51(C), pages 137-145.

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