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An environmental perspective on developing dual energy storage for electric vehicles - a case study exploring Al-ion vs. supercapacitors alongside Li-ion

An environmental perspective on developing dual energy storage for electric vehicles - a case study exploring Al-ion vs. supercapacitors alongside Li-ion
An environmental perspective on developing dual energy storage for electric vehicles - a case study exploring Al-ion vs. supercapacitors alongside Li-ion

Much focus of dual energy-storage systems (DESSs) for electric vehicles (EVs) has been on cost reduction and performance enhancement. While these are important in the development of better systems, the environmental impacts of system and component-level choices should not be overlooked. The current interest in EVs is primarily motivated by environmental reasons such as climate change mitigation and reduction of fossil fuel use, so it is important to develop environmentally sound alternatives at the design stage. Assessing the environmental impact of developmental and mature chemistries provides valuable insights into the technologies that need to be selected now and which to develop for the future. This paper presents a cradle-to-gate (i.e., all raw material and production elements are considered; however, the “use” phase and recycling are not) lifecycle assessment of a DESS with Li-ion and aqueous Al-ion cells and that of one with Li-ion cells and supercapacitors. These are also compared to a full Li-ion EV battery in terms of their environmental impact for both a bus and car case study. Key findings show that the use of a DESS overall reduces the environmental impacts over the vehicle lifetime and provides an argument for further development of aqueous Al-ion cells for this application.

aluminum-ion, dual energy-storage system, environmental impact assessment, hybrid energy-storage system, lifecycle assessment, supercapacitor
2296-598X
Melzack, N.
86c5295d-ebfc-49f6-a920-01c2bc91ab22
Wills, R.G.A.
60b7c98f-eced-4b11-aad9-fd2484e26c2c
Cruden, A.
ed709997-4402-49a7-9ad5-f4f3c62d29ab
Melzack, N.
86c5295d-ebfc-49f6-a920-01c2bc91ab22
Wills, R.G.A.
60b7c98f-eced-4b11-aad9-fd2484e26c2c
Cruden, A.
ed709997-4402-49a7-9ad5-f4f3c62d29ab

Melzack, N., Wills, R.G.A. and Cruden, A. (2024) An environmental perspective on developing dual energy storage for electric vehicles - a case study exploring Al-ion vs. supercapacitors alongside Li-ion. Frontiers in Energy Research, 11, [1266670]. (doi:10.3389/fenrg.2023.1266670).

Record type: Article

Abstract

Much focus of dual energy-storage systems (DESSs) for electric vehicles (EVs) has been on cost reduction and performance enhancement. While these are important in the development of better systems, the environmental impacts of system and component-level choices should not be overlooked. The current interest in EVs is primarily motivated by environmental reasons such as climate change mitigation and reduction of fossil fuel use, so it is important to develop environmentally sound alternatives at the design stage. Assessing the environmental impact of developmental and mature chemistries provides valuable insights into the technologies that need to be selected now and which to develop for the future. This paper presents a cradle-to-gate (i.e., all raw material and production elements are considered; however, the “use” phase and recycling are not) lifecycle assessment of a DESS with Li-ion and aqueous Al-ion cells and that of one with Li-ion cells and supercapacitors. These are also compared to a full Li-ion EV battery in terms of their environmental impact for both a bus and car case study. Key findings show that the use of a DESS overall reduces the environmental impacts over the vehicle lifetime and provides an argument for further development of aqueous Al-ion cells for this application.

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Accepted/In Press date: 6 December 2023
Published date: 4 January 2024
Additional Information: This work was funded by UKRI under an STFC Studentship and the EPSRC Faraday Training Grant EP/S514901/1. The open access datasets provided through Jens Peters (17) were also greatly appreciated. Publisher Copyright: Copyright © 2024 Melzack, Wills and Cruden.
Keywords: aluminum-ion, dual energy-storage system, environmental impact assessment, hybrid energy-storage system, lifecycle assessment, supercapacitor
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Identifiers

Local EPrints ID: 485713
URI: http://eprints.soton.ac.uk/id/eprint/485713
DOI: doi:10.3389/fenrg.2023.1266670
ISSN: 2296-598X
PURE UUID: caded46a-e91b-485b-aef4-c7fa0e3988c5
ORCID for N. Melzack: ORCID iD orcid.org/0000-0002-5578-4020
ORCID for R.G.A. Wills: ORCID iD orcid.org/0000-0002-4805-7589
ORCID for A. Cruden: ORCID iD orcid.org/0000-0003-3236-2535

Catalogue record

Date deposited: 15 Dec 2023 17:32
Last modified: 23 Mar 2024 03:03

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Contributors

Author: N. Melzack ORCID iD
Author: R.G.A. Wills ORCID iD
Author: A. Cruden ORCID iD

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