Di Lu, Ruhong Li, Muhammad Mominur Rahman, Pengyun Yu, Ling Lv, Sheng Yang, Yiqiang Huang, Chuangchao Sun, Shuoqing Zhang, Haikuo Zhang, Junbo Zhang, Xuezhang Xiao, Tao Deng, Liwu Fan, Lixin Chen, Jianping Wang, Enyuan Hu, Chunsheng Wang, Xiulin Fan
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The tiny solvent in the secondary solvation sheath pulls out the Li+ in the primary solvation sheath to form a fast ion-conduction ligand channel to enhance Li+ transport, while the small-sized solvent with low solvation energy also allows the anion to enter the first Li+ solvation shell to form an inorganic-rich interphase. The electrolyte-design concept is demonstrated by using fluoroacetonitrile (FAN) solvent. The electrolyte of 1.3 M lithium bis(fluorosulfonyl)imide (LiFSI) in FAN exhibits ultrahigh ionic conductivity of 40.3 mS cm−1 at 25 °C and 11.9 mS cm−1 even at −70 °C, thus enabling 4.5-V graphite||LiNi0.8Mn0.1Co0.1O2 pouch cells (1.2 Ah, 2.85 mAh cm−2) to achieve high reversibility (0.62 Ah) when the cells are charged and discharged even at −65 °C. The electrolyte with small-sized solvents enables LIBs to simultaneously achieve high energy density, fast charging and a wide operating temperature range, which is unattainable for the current electrolyte design but is highly desired for extreme LIBs. This mechanism is generalizable and can be expanded to other metal-ion battery electrolytes. 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Here we report guidelines for designing such electrolytes by using small-sized solvents with low solvation energy. The tiny solvent in the secondary solvation sheath pulls out the Li+ in the primary solvation sheath to form a fast ion-conduction ligand channel to enhance Li+ transport, while the small-sized solvent with low solvation energy also allows the anion to enter the first Li+ solvation shell to form an inorganic-rich interphase. The electrolyte-design concept is demonstrated by using fluoroacetonitrile (FAN) solvent. The electrolyte of 1.3 M lithium bis(fluorosulfonyl)imide (LiFSI) in FAN exhibits ultrahigh ionic conductivity of 40.3 mS cm−1 at 25 °C and 11.9 mS cm−1 even at −70 °C, thus enabling 4.5-V graphite||LiNi0.8Mn0.1Co0.1O2 pouch cells (1.2 Ah, 2.85 mAh cm−2) to achieve high reversibility (0.62 Ah) when the cells are charged and discharged even at −65 °C. 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引用次数: 0
摘要
电动汽车和航空用锂离子电池(LIB)要求高能量密度、快速充电和宽工作温度范围,而这几乎是不可能实现的,因为它们要求电解质同时具有高离子电导率、低溶解能和低熔点,并形成阴离子衍生的无机相间1-5。在此,我们报告了通过使用具有低溶解能的小型溶剂来设计此类电解质的指南。二级溶解鞘中的微小溶剂可将一级溶解鞘中的 Li+ 拉出,形成快速离子传导配体通道,从而增强 Li+ 的传输;而具有低溶解能的小型溶剂还可让阴离子进入一级 Li+ 溶解鞘,形成富含无机物的中间相。电解质设计理念通过使用氟乙腈(FAN)溶剂得到了验证。在 FAN 中的 1.3 M 双(氟磺酰)亚胺锂(LiFSI)电解质在 25 °C 时具有 40.3 mS cm-1 的超高离子电导率,即使在 -70 °C 时也能达到 11.9 mS cm-1,从而使 4.5-V石墨||锂镍0.8Mn0.1Co0.1O2袋装电池(1.2 Ah, 2.85 mAh cm-2)在零下65 °C充放电时也能达到很高的可逆性(0.62 Ah)。含有小体积溶剂的电解质可使锂电池同时实现高能量密度、快速充电和宽工作温度范围,这在目前的电解质设计中是无法实现的,但却是极端锂电池所亟需的。这种机制具有通用性,可扩展到其他金属离子电池电解质。
Li-ion batteries (LIBs) for electric vehicles and aviation demand high energy density, fast charging and a wide operating temperature range, which are virtually impossible because they require electrolytes to simultaneously have high ionic conductivity, low solvation energy and low melting point and form an anion-derived inorganic interphase1–5. Here we report guidelines for designing such electrolytes by using small-sized solvents with low solvation energy. The tiny solvent in the secondary solvation sheath pulls out the Li+ in the primary solvation sheath to form a fast ion-conduction ligand channel to enhance Li+ transport, while the small-sized solvent with low solvation energy also allows the anion to enter the first Li+ solvation shell to form an inorganic-rich interphase. The electrolyte-design concept is demonstrated by using fluoroacetonitrile (FAN) solvent. The electrolyte of 1.3 M lithium bis(fluorosulfonyl)imide (LiFSI) in FAN exhibits ultrahigh ionic conductivity of 40.3 mS cm−1 at 25 °C and 11.9 mS cm−1 even at −70 °C, thus enabling 4.5-V graphite||LiNi0.8Mn0.1Co0.1O2 pouch cells (1.2 Ah, 2.85 mAh cm−2) to achieve high reversibility (0.62 Ah) when the cells are charged and discharged even at −65 °C. The electrolyte with small-sized solvents enables LIBs to simultaneously achieve high energy density, fast charging and a wide operating temperature range, which is unattainable for the current electrolyte design but is highly desired for extreme LIBs. This mechanism is generalizable and can be expanded to other metal-ion battery electrolytes. An electrolyte design using small-sized fluoroacetonitrile solvents to form a ligand channel produces lithium-ion batteries simultaneously achieving high energy density, fast charging and wide operating temperature range, desirable features for batteries working in extreme conditions.
期刊介绍:
Nature is a prestigious international journal that publishes peer-reviewed research in various scientific and technological fields. The selection of articles is based on criteria such as originality, importance, interdisciplinary relevance, timeliness, accessibility, elegance, and surprising conclusions. In addition to showcasing significant scientific advances, Nature delivers rapid, authoritative, insightful news, and interpretation of current and upcoming trends impacting science, scientists, and the broader public. The journal serves a dual purpose: firstly, to promptly share noteworthy scientific advances and foster discussions among scientists, and secondly, to ensure the swift dissemination of scientific results globally, emphasizing their significance for knowledge, culture, and daily life.