Prospective life cycle assessment of an electric vehicle equipped with a model magnesium battery

IF 4.6 3区工程技术 Q2 ENERGY & FUELS Energy, Sustainability and Society Pub Date : 2024-07-18 DOI:10.1186/s13705-024-00475-y

Sebastián Pinto-Bautista, Manuel Baumann, Marcel Weil

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Abstract

Background

Concerns about the sustainability of commercially available batteries have driven the development of post-lithium systems. While previous studies on Magnesium batteries have explored both the potential environmental footprint of battery production and their possible use in stationary applications, their environmental impact in electromobility remains unexplored. This study provides an initial prospective evaluation of the environmental performance of a theoretical Mg–S battery for potential use in electric vehicles (EVs). Utilizing life cycle assessment (LCA) methodology, various scenarios are analyzed and compared to conventional systems. The analysis focuses on potential environmental impacts, including climate change, resource criticality, acidification of the biosphere, and particulate matter emissions.

Results

In the battery pack level, the Magnesium anode and its respective supply chain have been identified as main drivers of environmental burdens. Additional concerns arise from the uneven geographical distribution of Mg production, which leads to dependency on few producers. In terms of resource criticality, the Mg–S battery could carry significant advantages over benchmark systems. A look into the use-phase via theoretical implementation in an electric vehicle (EV) also suggests that the Magnesium based EV could perform on a comparable level to an LIB EV, also outperforming conventional ICEVs in several impact categories.

Conclusions

This study is based on optimistic assumptions, acknowledging several remaining technical challenges for the Mg battery. Consequently, the results are indicative and carry a significant degree of uncertainty. Nonetheless, they suggest that the Mg–S system shows promising environmental sustainability performance, comparable to other reference systems.

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对配备镁电池模型的电动汽车进行前瞻性生命周期评估

背景对市售电池可持续性的担忧推动了后锂电池系统的发展。以前对镁电池的研究探讨了电池生产的潜在环境足迹及其在固定应用中的可能用途，但对其在电动汽车中的环境影响仍未进行探讨。本研究对电动汽车（EV）中可能使用的理论镁-S 电池的环境性能进行了初步的前瞻性评估。利用生命周期评估（LCA）方法，对各种方案进行了分析，并与传统系统进行了比较。分析的重点是潜在的环境影响，包括气候变化、资源临界性、生物圈酸化和微粒物质排放。由于镁生产的地理分布不均，导致对少数生产商的依赖，从而引发了其他问题。就资源临界性而言，与基准系统相比，镁-S 电池具有显著优势。通过在电动汽车（EV）中的理论实施对使用阶段的考察也表明，基于镁的电动汽车的性能可与锂电池电动汽车相媲美，在几个影响类别中也优于传统的内燃机汽车。因此，研究结果是指示性的，具有很大的不确定性。不过，这些结果表明，镁-S 系统在环境可持续发展方面表现良好，可与其他参考系统相媲美。

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来源期刊

Energy, Sustainability and Society Energy-Energy Engineering and Power Technology

CiteScore

9.60

自引率

4.10%

发文量

审稿时长

13 weeks

期刊介绍： Energy, Sustainability and Society is a peer-reviewed open access journal published under the brand SpringerOpen. It covers topics ranging from scientific research to innovative approaches for technology implementation to analysis of economic, social and environmental impacts of sustainable energy systems.