从低浓度Li+水溶液中直接提取锂的技术综述

IF 2.5 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Frontiers in chemical engineering Pub Date : 2022-11-30 DOI:10.3389/fceng.2022.1008680
Olivia Murphy, M. Haji
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引用次数: 6

摘要

根据《联合国气候变化框架公约》制定的《巴黎协定》,许多国家已同意将其能源和技术转型,以将温室气体排放量降至与升温1.5°C目标一致的水平。锂(Li)对这一转变至关重要,因为它用于核聚变以及用于电动汽车储能和可再生能源收集系统的可充电锂离子电池。因此,到2050年,全球对锂的需求预计将达到511万吨。按照这个消耗速度,预计到2080年,李在土地上的储量将耗尽。除了锂辉石和锂云母矿石外,海水中还含有锂,盐湖卤水中也含有溶解的锂离子。从这样的水溶液中回收Li是有限陆地储量的潜在解决方案。本工作综述了从水溶液中回收锂的各种技术的优势和挑战,包括沉淀剂、溶剂萃取剂、锂离子筛、锂离子印迹膜、基于电池的电化学系统和基于电膜的电化学系统。每种技术的技术经济可行性和关键性能参数,如Li+容量、选择性、分离效率、回收、再生、循环稳定性、热稳定性、环境耐久性、产品质量、提取时间和能耗,在可用的情况下都会得到强调。不包括沉淀和溶剂提取,这些技术显示出从低Li+浓度的水溶液或海水中可持续提取Li+的高潜力。然而,要将这些技术从台式实验扩展到工业应用,还需要进一步的研究和开发。应优先开发可提高Li+选择性、分离效率、化学稳定性、寿命和Li+回收率的优化材料和合成方法。此外,还需要进行技术经济和生命周期分析,以便对大规模锂生产的这些提取技术进行更关键的评估。这些评估将进一步阐明气候影响、能源需求、资本成本、运营成本、生产力、潜在投资回报和其他关键可行性因素。预计这篇综述将为未来的研究商业化努力提供坚实的基础,以可持续地满足随着世界向清洁能源转型对李日益增长的需求。
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A review of technologies for direct lithium extraction from low Li+ concentration aqueous solutions
Under the Paris Agreement, established by the United Nations Framework Convention on Climate Change, many countries have agreed to transition their energy sources and technologies to reduce greenhouse gas emissions to levels concordant with the 1.5°C warming goal. Lithium (Li) is critical to this transition due to its use in nuclear fusion as well as in rechargeable lithium-ion batteries used for energy storage for electric vehicles and renewable energy harvesting systems. As a result, the global demand for Li is expected to reach 5.11 Mt by 2050. At this consumption rate, the Li reserves on land are expected to be depleted by 2080. In addition to spodumene and lepidolite ores, Li is present in seawater, and salt-lake brines as dissolved Li+ ions. Li recovery from aqueous solutions such as these are a potential solution to limited terrestrial reserves. The present work reviews the advantages and challenges of a variety of technologies for Li recovery from aqueous solutions, including precipitants, solvent extractants, Li-ion sieves, Li-ion-imprinted membranes, battery-based electrochemical systems, and electro-membrane-based electrochemical systems. The techno-economic feasibility and key performance parameters of each technology, such as the Li+ capacity, selectivity, separation efficiency, recovery, regeneration, cyclical stability, thermal stability, environmental durability, product quality, extraction time, and energy consumption are highlighted when available. Excluding precipitation and solvent extraction, these technologies demonstrate a high potential for sustainable Li+ extraction from low Li+ concentration aqueous solutions or seawater. However, further research and development will be required to scale these technologies from benchtop experiments to industrial applications. The development of optimized materials and synthesis methods that improve the Li+ selectivity, separation efficiency, chemical stability, lifetime, and Li+ recovery should be prioritized. Additionally, techno-economic and life cycle analyses are needed for a more critical evaluation of these extraction technologies for large-scale Li production. Such assessments will further elucidate the climate impact, energy demand, capital costs, operational costs, productivity, potential return on investment, and other key feasibility factors. It is anticipated that this review will provide a solid foundation for future research commercialization efforts to sustainably meet the growing demand for Li as the world transitions to clean energy.
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3.50
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13 weeks
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