Fei Pei, Yimeng Huang, Lin Wu, Shiyuan Zhou, Qi Kang, Wenjie Lin, Yaqi Liao, Yi Zhang, Kai Huang, Yue Shen, Lixia Yuan, Shi-gang Sun, Zhen Li, Yunhui Huang
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引用次数: 0
摘要
在高压锂金属电池中使用固态聚合物电解质(SPEs)是实现高能量密度和安全性的一种有前途的策略。然而,固态聚合物电解质面临着不理想的机械强度、低离子电导率和高压界面不兼容等挑战。本文制备了一种新型交联聚(醚-聚氨酯)基 SPE,它具有分子交联结构,可创建高通量的 Li+ 传输通道。其中引入了氨基修饰的锆卟啉基金属有机框架(ZrMOF)作为多位交联节点和聚合物链延伸剂。SPE 中丰富的醚/酮/氧和路易斯酸位点实现了较高的 Li+ 导电性(30 °C 时为 5.7 × 10-4 S cm-1)和 Li+ 传递数(0.84)。SPE 的互穿交联结构具有很强的机械强度,因此在 Li||Li 对称电池中的循环寿命达到了创纪录的 8000 小时。ZrMOF 的高结构稳定性和高氧化电位(5.1 V)的 SPE 中丰富的抽电子氨基甲酸酯/氨基甲酸酯基团使其在镍钴锰锂电池中经过 500 次循环后,在 0.3 C 下的放电容量达到 182 mAh g-1。值得注意的是,在高负载阴极(≈4 mAh cm-2)条件下,1.5 Ah 袋装电池的能量密度高达 446 Wh kg-1,这表明当前的 SPE 在固态高压金属锂电池中的实际应用前景十分广阔。
Multisite Crosslinked Poly(ether-urethane)-Based Polymer Electrolytes for High-Voltage Solid-State Lithium Metal Batteries
Utilizing solid-state polymer electrolytes (SPEs) in high-voltage Li-metal batteries is a promising strategy for achieving high energy density and safety. However, the SPEs face the challenges such as undesirable mechanical strength, low ionic conductivity and incompatible high-voltage interface. Here, a novel crosslinked poly(ether-urethane)-based SPE with a molecular cross-linked structure is fabricated to create high-throughput Li+ transport pathway. The amino-modified Zr-porphyrin-based metal-organic frameworks (ZrMOF) are introduced as multisite cross-linking nodes and polymer chain extenders. The abundant ether/ketonic-oxygen and Lewis acid sites in the SPE achieve high Li+ conductivity (5.7 × 10−4 S cm−1 at 30 °C) and Li+ transference number (0.84). The interpenetrating cross-linked structure of SPE with robust mechanical strength results in a record cycle life of 8000 h in Li||Li symmetric cell. The high structural stability of ZrMOF and abundant electron-withdrawing urethane/ureido groups in the SPE with high oxidation potential (5.1 V) enables a discharge capacity of 182 mAh g−1 at 0.3 C over 500 cycles in a LiNi0.8Co0.1Mn0.1O2||Li cell. Remarkably, a high energy density of 446 Wh kg−1 in a 1.5-Ah pouch cell is obtained with high loading cathode (≈4 mAh cm−2), demonstrating a great prospect of the current SPE for practical application in solid-state, high-voltage Li-metal batteries.
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