清洁能源转型的关键金属需求:交通电气化案例的定量回顾

IF 13 Q1 ENERGY & FUELS
Chunbo Zhang , Jinyue Yan , Fengqi You
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引用次数: 11

摘要

清洁能源转型在实现减缓气候变化目标方面发挥着至关重要的作用。在交通运输领域,电池和燃料电池电动汽车(ev)已成为减少交通运输温室气体排放的关键解决方案。然而,电动汽车的快速普及引发了锂离子电池和燃料电池生产中使用的关键金属(如锂、镍、钴、铂族金属等)的潜在供应风险。物质流分析(MFA)已被广泛应用于不同时空尺度的交通电气化关键金属需求评估。本文对78篇MFA关于交通电气化临界金属需求的研究论文进行了定量回顾和分析。我们分析了所选研究的地理和时间范围、交通部门、电动汽车类别、电池技术、材料和建模方法的特点。根据这些研究中的全球预测,我们比较了最受关注的四种金属的年度和累积全球需求:锂、镍、钴和铂族金属。尽管存在重大不确定性,但大多数研究表明,这四种金属的年需求量将继续增加,并在2021年远远超过其生产能力。这些金属的全球储备可以满足短期(2020-2030)和中期(2020-2050)的累积需求,但不足以满足长期(2020-2100)的需求。然后,我们总结了这些研究提出的政策含义。最后,我们从四个方面讨论了主要发现:部署电动汽车的环境和社会影响,是否对重型汽车进行电动化,回收利用的机遇和挑战,以及未来的研究方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Critical metal requirement for clean energy transition: A quantitative review on the case of transportation electrification

The clean energy transition plays an essential role in achieving climate mitigation targets. As for the transportation sector, battery and fuel cell electric vehicles (EVs) have emerged as a key solution to reduce greenhouse gasses from transportation emissions. However, the rapid uptake of EVs has triggered potential supply risks of critical metals (e.g., lithium, nickel, cobalt, platinum group metals (PGMs), etc.) used in the production of lithium-ion batteries and fuel cells. Material flow analysis (MFA) has been widely applied to assess the demand for critical metals used in transportation electrification on various spatiotemporal scales. This paper presents a quantitative review and analysis of 78 MFA research articles on the critical metal requirement of transportation electrification. We analyzed the characteristics of the selected studies regarding their geographical and temporal scopes, transportation sectors, EV categories, battery technologies, materials, and modeling approaches. Based on the global forecasts in those studies, we compared the annual and cumulative global requirements of the four metals that received the most attention: lithium, nickel, cobalt, and PGMs. Although major uncertainties exist, most studies indicate that the annual demand for these four metals will continue to increase and far exceed their production capacities in 2021. Global reserves of these metals may meet their cumulative demand in the short-term (2020–2030) and medium-term (2020–2050) but are insufficient for the long-term (2020–2100) needs. Then, we summarized the proposed policy implications in these studies. Finally, we discuss the main findings from the four aspects: environmental and social implications of deploying electric vehicles, whether or not to electrify heavy-duty vehicles, opportunities and challenges in recycling, and future research direction.

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来源期刊
Advances in Applied Energy
Advances in Applied Energy Energy-General Energy
CiteScore
23.90
自引率
0.00%
发文量
36
审稿时长
21 days
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