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Well‐to‐wheels analysis of greenhouse gas emissions for passenger vehicles in Middle East and North Africa

Author

Listed:
  • Sharath Ankathi
  • Yu Gan
  • Zifeng Lu
  • James A. Littlefield
  • Liang Jing
  • Farah O. Ramadan
  • Jean‐Christophe Monfort
  • Alhassan Badahdah
  • Hassan El‐Houjeiri
  • Michael Wang

Abstract

Battery electric vehicles (BEVs) are widely considered a pathway to achieve low carbon mobility. BEVs emit zero emissions from the tailpipe, but their life cycle carbon reduction compared to gasoline vehicles varies based on primary energy sources, electricity generation, and use efficiency. The Middle East and North Africa (MENA) region is an area rich in fossil fuels, meriting a detailed comparison between the emissions from BEV and other powertrains. We developed a MENA‐specific life cycle model that estimates well‐to‐wheel (WTW) greenhouse gas (GHG) emissions from passenger transport with internal combustion engine vehicles (ICEVs), hybrid electric vehicles (HEVs), plug‐in hybrid electric vehicles, and BEVs. MENA's average WTW GHG emissions for all supply chain steps including combustion emissions from vehicle operation are 767 g/kWh and 84 g CO2eq/MJ for electricity and gasoline, respectively, but are highly variable due to heterogeneity in upstream supply chains. The use of hybrid gasoline ICEVs provides the largest emission reduction opportunity for existing vehicle fleets in 9 of the 16 MENA countries. For these nine countries, replacing gasoline ICEVs with HEVs could, on average, reduce country‐level life cycle GHG emissions by 47%. There is a similar emission reduction opportunity for 14 of the 16 MENA countries when normalizing vehicle efficiencies irrespective of the powertrain shares and other trends in existing vehicle fleets. Future scenario analysis shows that BEVs would have the lowest WTW GHG emissions among all powertrains in most MENA countries only if significantly reduced electricity transmission losses and cleaner grid mix are realized, although a high cost of infrastructure developments is expected.

Suggested Citation

  • Sharath Ankathi & Yu Gan & Zifeng Lu & James A. Littlefield & Liang Jing & Farah O. Ramadan & Jean‐Christophe Monfort & Alhassan Badahdah & Hassan El‐Houjeiri & Michael Wang, 2024. "Well‐to‐wheels analysis of greenhouse gas emissions for passenger vehicles in Middle East and North Africa," Journal of Industrial Ecology, Yale University, vol. 28(4), pages 800-812, August.
    • Handle: RePEc:bla:inecol:v:28:y:2024:i:4:p:800-812
    DOI: 10.1111/jiec.13500
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    References listed on IDEAS

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    1. Rangaraju, Surendraprabu & De Vroey, Laurent & Messagie, Maarten & Mertens, Jan & Van Mierlo, Joeri, 2015. "Impacts of electricity mix, charging profile, and driving behavior on the emissions performance of battery electric vehicles: A Belgian case study," Applied Energy, Elsevier, vol. 148(C), pages 496-505.
    2. Varga, Bogdan Ovidiu, 2013. "Electric vehicles, primary energy sources and CO2 emissions: Romanian case study," Energy, Elsevier, vol. 49(C), pages 61-70.
    3. Amro Elshurafa & Nawaz Peerbocus, 2019. "Electric Vehicle Deployment and Carbon Emissions in Saudi Arabia: A Power System Perspective," Discussion Papers ks--2019-dp76, King Abdullah Petroleum Studies and Research Center.
    4. Xiaoyang Zhong & Mingming Hu & Sebastiaan Deetman & Bernhard Steubing & Hai Xiang Lin & Glenn Aguilar Hernandez & Carina Harpprecht & Chunbo Zhang & Arnold Tukker & Paul Behrens, 2021. "Global greenhouse gas emissions from residential and commercial building materials and mitigation strategies to 2060," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    5. Mansour, Charbel J. & Haddad, Marc G., 2017. "Well-to-wheel assessment for informing transition strategies to low-carbon fuel-vehicles in developing countries dependent on fuel imports: A case-study of road transport in Lebanon," Energy Policy, Elsevier, vol. 107(C), pages 167-181.
    6. Yu Gan & Hassan M. El-Houjeiri & Alhassan Badahdah & Zifeng Lu & Hao Cai & Steven Przesmitzki & Michael Wang, 2020. "Carbon footprint of global natural gas supplies to China," Nature Communications, Nature, vol. 11(1), pages 1-9, December.
    7. Sharath Ankathi & Zifeng Lu & George G. Zaimes & Troy Hawkins & Yu Gan & Michael Wang, 2022. "Greenhouse gas emissions from the global transportation of crude oil: Current status and mitigation potential," Journal of Industrial Ecology, Yale University, vol. 26(6), pages 2045-2056, December.
    8. Peter Erickson & Michael Lazarus & Georgia Piggot, 2018. "Limiting fossil fuel production as the next big step in climate policy," Nature Climate Change, Nature, vol. 8(12), pages 1037-1043, December.
    9. Onat, Nuri Cihat & Kucukvar, Murat & Tatari, Omer, 2015. "Conventional, hybrid, plug-in hybrid or electric vehicles? State-based comparative carbon and energy footprint analysis in the United States," Applied Energy, Elsevier, vol. 150(C), pages 36-49.
    10. Liang Jing & Hassan M. El-Houjeiri & Jean-Christophe Monfort & Adam R. Brandt & Mohammad S. Masnadi & Deborah Gordon & Joule A. Bergerson, 2020. "Carbon intensity of global crude oil refining and mitigation potential," Nature Climate Change, Nature, vol. 10(6), pages 526-532, June.
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