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Evaluating multiple emission pathways for fixed cumulative carbon dioxide emissions from global-scale socioeconomic perspectives

Author

Listed:
  • Ken’ichi Matsumoto

    (Nagasaki University
    Japan Agency for Marine-Earth Science and Technology)

  • Kaoru Tachiiri

    (Japan Agency for Marine-Earth Science and Technology)

  • Michio Kawamiya

    (Japan Agency for Marine-Earth Science and Technology)

Abstract

Recent climate modeling studies have concluded that cumulative carbon emissions determine temperature increase, regardless of emission pathways. Accordingly, the optimal emission pathway can be determined from a socioeconomic standpoint. To access the path dependence of socioeconomic impacts for cumulative carbon emissions, we used a computable general equilibrium model to analyze impacts on major socioeconomic indicators on a global scale for 30–50 pathways with different emission reduction starting years, different subsequent emission pathways, and three different cumulative 2100 emission scenarios (emissions that meet the 2 °C target, the 2 °C target emissions plus 10 %, and emissions producing radiative forcing of 4.5 W/m2). The results show that even with identical cumulative emission figures, the resulting socioeconomic impacts vary by the pathway realized. For the United Nations 2 °C target, for example, (a) the 95 % confidence interval of cumulative global gross domestic product (GDP) is 1355–1363 trillion US dollars (2010–2100, discount rate = 5 %), (b) the cumulative GDP of pathways with later emission reduction starting years grows weaker (5 % significance level), and (c) emissions in 2100 have a moderate negative correlation with cumulative GDP. These results suggest that GDP loss is minimized with pathways with earlier emission reduction followed by more moderate reduction rates to achieve lower emission levels. Consequently, we suggest an early emission peak to meet the stringent target. In our model setting, it is desirable for emissions to peak by 2020 to reduce mitigation cost and by 2030 at the latest to meet the 2 °C target.

Suggested Citation

  • Ken’ichi Matsumoto & Kaoru Tachiiri & Michio Kawamiya, 2018. "Evaluating multiple emission pathways for fixed cumulative carbon dioxide emissions from global-scale socioeconomic perspectives," Mitigation and Adaptation Strategies for Global Change, Springer, vol. 23(1), pages 1-26, January.
    • Handle: RePEc:spr:masfgc:v:23:y:2018:i:1:d:10.1007_s11027-016-9726-8
    DOI: 10.1007/s11027-016-9726-8
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    References listed on IDEAS

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    1. Matsumoto, Ken׳ichi & Andriosopoulos, Kostas, 2016. "Energy security in East Asia under climate mitigation scenarios in the 21st century," Omega, Elsevier, vol. 59(PA), pages 60-71.
    2. Toshihiko Masui & Kenichi Matsumoto & Yasuaki Hijioka & Tsuguki Kinoshita & Toru Nozawa & Sawako Ishiwatari & Etsushi Kato & P. Shukla & Yoshiki Yamagata & Mikiko Kainuma, 2011. "An emission pathway for stabilization at 6 Wm −2 radiative forcing," Climatic Change, Springer, vol. 109(1), pages 59-76, November.
    3. Okagawa, Azusa & Masui, Toshihiko & Akashi, Osamu & Hijioka, Yasuaki & Matsumoto, Kenichi & Kainuma, Mikiko, 2012. "Assessment of GHG emission reduction pathways in a society without carbon capture and nuclear technologies," Energy Economics, Elsevier, vol. 34(S3), pages 391-398.
    4. H. Damon Matthews & Nathan P. Gillett & Peter A. Stott & Kirsten Zickfeld, 2009. "The proportionality of global warming to cumulative carbon emissions," Nature, Nature, vol. 459(7248), pages 829-832, June.
    5. Ottmar Edenhofer , Brigitte Knopf, Terry Barker, Lavinia Baumstark, Elie Bellevrat, Bertrand Chateau, Patrick Criqui, Morna Isaac, Alban Kitous, Socrates Kypreos, Marian Leimbach, Kai Lessmann, Bertra, 2010. "The Economics of Low Stabilization: Model Comparison of Mitigation Strategies and Costs," The Energy Journal, International Association for Energy Economics, vol. 0(Special I).
    6. Malte Meinshausen & Nicolai Meinshausen & William Hare & Sarah C. B. Raper & Katja Frieler & Reto Knutti & David J. Frame & Myles R. Allen, 2009. "Greenhouse-gas emission targets for limiting global warming to 2 °C," Nature, Nature, vol. 458(7242), pages 1158-1162, April.
    7. Myles R. Allen & David J. Frame & Chris Huntingford & Chris D. Jones & Jason A. Lowe & Malte Meinshausen & Nicolai Meinshausen, 2009. "Warming caused by cumulative carbon emissions towards the trillionth tonne," Nature, Nature, vol. 458(7242), pages 1163-1166, April.
    8. R. Warren & J. Lowe & N. Arnell & C. Hope & P. Berry & S. Brown & A. Gambhir & S. Gosling & R. Nicholls & J. O’Hanley & T. Osborn & T. Osborne & J. Price & S. Raper & G. Rose & J. Vanderwal, 2013. "The AVOID programme’s new simulations of the global benefits of stringent climate change mitigation," Climatic Change, Springer, vol. 120(1), pages 55-70, September.
    9. Michael Jakob & Gunnar Luderer & Jan Steckel & Massimo Tavoni & Stephanie Monjon, 2012. "Time to act now? Assessing the costs of delaying climate measures and benefits of early action," Climatic Change, Springer, vol. 114(1), pages 79-99, September.
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    Cited by:

    1. Nathalie Spittler & Ganna Gladkykh & Arnaud Diemer & Brynhildur Davidsdottir, 2019. "Understanding the Current Energy Paradigm and Energy System Models for More Sustainable Energy System Development," Post-Print hal-02127724, HAL.
    2. Qiong Chen & Hongyu Zhang & Yui-Yip Lau & Tianni Wang & Wen Wang & Guangsheng Zhang, 2023. "Climate Change, Carbon Peaks, and Carbon Neutralization: A Bibliometric Study from 2006 to 2023," Sustainability, MDPI, vol. 15(7), pages 1-12, March.
    3. Matsumoto, Ken’ichi & Shiraki, Hiroto, 2018. "Energy security performance in Japan under different socioeconomic and energy conditions," Renewable and Sustainable Energy Reviews, Elsevier, vol. 90(C), pages 391-401.
    4. Nathalie Spittler & Ganna Gladkykh & Arnaud Diemer & Brynhildur Davidsdottir, 2019. "Understanding the Current Energy Paradigm and Energy System Models for More Sustainable Energy System Development," Energies, MDPI, vol. 12(8), pages 1-22, April.
    5. Silva Herran, Diego & Tachiiri, Kaoru & Matsumoto, Ken'ichi, 2019. "Global energy system transformations in mitigation scenarios considering climate uncertainties," Applied Energy, Elsevier, vol. 243(C), pages 119-131.

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