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Vehicles and Critical Raw Materials: A Sustainability Assessment Using Thermodynamic Rarity

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  • Abel Ortego
  • Alicia Valero
  • Antonio Valero
  • Eliette Restrepo

Abstract

The changing material composition of cars represents a challenge for future recycling of end‐of‐life vehicles (ELVs). Particularly, as current recycling targets are based solely on mass, critical metals increasingly used in cars might be lost during recycling processes, due to their small mass compared to bulk metals such as Fe and Al. We investigate a complementary indicator to material value in passenger vehicles based on exergy. The indicator is called thermodynamic rarity and represents the exergy cost (GJ) needed for producing a given material from bare rock to the market. According to our results, the thermodynamic rarity of critical metals used in cars, in most cases, supersedes that of the bulk metals that are the current focus of ELV recycling. While Fe, Al, and Cu account for more than 90% of the car's metal content, they only represent 60% of the total rarity of a car. In contrast, while Mo, Co, Nb, and Ni account for less than 1% of the car's metal content, their contribution to the car's rarity is larger than 7%. Rarity increases with the electrification level due to the greater amount of critical metals used; specifically, due to an increased use of (1) Al alloys are mainly used in the car's body‐in‐white of electric cars for light‐weighting purposes, (2) Cu in car electronics, and (3) Co, Li, Ni, and rare earth metals (La, Nd, and Pr) in Li‐ion and NiMH batteries.

Suggested Citation

  • Abel Ortego & Alicia Valero & Antonio Valero & Eliette Restrepo, 2018. "Vehicles and Critical Raw Materials: A Sustainability Assessment Using Thermodynamic Rarity," Journal of Industrial Ecology, Yale University, vol. 22(5), pages 1005-1015, October.
    • Handle: RePEc:bla:inecol:v:22:y:2018:i:5:p:1005-1015
    DOI: 10.1111/jiec.12737
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    References listed on IDEAS

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    2. Alicia Valero & Antonio Valero, 2013. "From Grave to Cradle," Journal of Industrial Ecology, Yale University, vol. 17(1), pages 43-52, February.
    3. Hajime Ohno & Kazuyo Matsubae & Kenichi Nakajima & Shinichiro Nakamura & Tetsuya Nagasaka, 2014. "Unintentional Flow of Alloying Elements in Steel during Recycling of End-of-Life Vehicles," Journal of Industrial Ecology, Yale University, vol. 18(2), pages 242-253, April.
    4. Valero, Antonio & Agudelo, Andrés & Valero, Alicia, 2011. "The crepuscular planet. A model for the exhausted atmosphere and hydrosphere," Energy, Elsevier, vol. 36(6), pages 3745-3753.
    5. Valero, Alicia & Valero, Antonio & Vieillard, Philippe, 2012. "The thermodynamic properties of the upper continental crust: Exergy, Gibbs free energy and enthalpy," Energy, Elsevier, vol. 41(1), pages 121-127.
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    2. Valero, Alicia & Valero, Antonio & Calvo, Guiomar & Ortego, Abel, 2018. "Material bottlenecks in the future development of green technologies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 93(C), pages 178-200.
    3. Mona Arnold & Elina Pohjalainen & Sören Steger & Wolfgang Kaerger & Jan-Henk Welink, 2021. "Economic Viability of Extracting High Value Metals from End of Life Vehicles," Sustainability, MDPI, vol. 13(4), pages 1-12, February.
    4. Philip Cooke, 2021. "The Lithium Wars: From Kokkola to the Congo for the 500 Mile Battery," Sustainability, MDPI, vol. 13(8), pages 1-13, April.
    5. Thomas Fruergaard Astrup & Kostyantyn Pivnenko & Marie Kampmann Eriksen & Alessio Boldrin, 2018. "Life Cycle Assessment of Waste Management: Are We Addressing the Key Challenges Ahead of Us?," Journal of Industrial Ecology, Yale University, vol. 22(5), pages 1000-1004, October.
    6. Kieran Campbell‐Johnston & Erik Roos Lindgreen & Giovanni Mondello & Teresa Maria Gulotta & Walter J. V. Vermeulen & Roberta Salomone, 2023. "Thermodynamic rarity of electrical and electronic waste: Assessment and policy implications for critical materials," Journal of Industrial Ecology, Yale University, vol. 27(2), pages 508-521, April.
    7. Bruno Jetin, 2020. "Who will control the electric vehicle market?," International Journal of Automotive Technology and Management, Inderscience Enterprises Ltd, vol. 20(2), pages 156-177.
    8. Sofia Russo & Alicia Valero & Antonio Valero & Marta Iglesias-Émbil, 2021. "Exergy-Based Assessment of Polymers Production and Recycling: An Application to the Automotive Sector," Energies, MDPI, vol. 14(2), pages 1-19, January.
    9. Marta Iglesias-Émbil & Alejandro Abadías & Alicia Valero & Guiomar Calvo & Markus Andreas Reuter & Abel Ortego, 2022. "Criticality and Recyclability Assessment of Car Parts—A Thermodynamic Simulation-Based Approach," Sustainability, MDPI, vol. 15(1), pages 1-22, December.
    10. Eliette Restrepo & Amund N. Løvik & Rolf Widmer & Patrick Wäger & Daniel B. Müller, 2019. "Historical Penetration Patterns of Automobile Electronic Control Systems and Implications for Critical Raw Materials Recycling," Resources, MDPI, vol. 8(2), pages 1-20, March.
    11. F. P. Brito & Jorge Martins & Francisco Lopes & Carlos Castro & Luís Martins & A. L. N. Moreira, 2020. "Development and Assessment of an Over-Expanded Engine to be Used as an Efficiency-Oriented Range Extender for Electric Vehicles," Energies, MDPI, vol. 13(2), pages 1-18, January.
    12. Tian, Xu & Geng, Yong & Sarkis, Joseph & Gao, Cuixia & Sun, Xin & Micic, Tatyana & Hao, Han & Wang, Xin, 2021. "Features of critical resource trade networks of lithium-ion batteries," Resources Policy, Elsevier, vol. 73(C).

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