Isotropic Structure and Polymer Interface Intensified Lithium-Ion Transmission in Spherical Graphite Tailings/Coke Composite Anode

kaixuan Bian, Yue Meng, Yu Fu, Lili Feng, Zhi Wang, Junhao Liu, Xuzhong Gong
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Abstract

Spherical graphite tailings (SGT) as the anode electrode for a lithium-ion battery not only improves the utilization value of SGT as solid waste, but also demonstrates the cleaner production of natural flake graphite (NG) compared with artificial graphite. However, SGT anodes present issues regarding rate performance and cycle stability due to the anisotropy structure and the instability of the solid electrolyte interface (SEI). In this work, a composite anode with isotropic structure was prepared by granulation of high-sulfur coal (HSC) and SGT, while an artificial SEI was prepared utilizing polyether amine/polyvinyl pyrrolidone (PEA/PVP) crosslinked polymer. Results showed that the coke from HSC pyrolysis enhanced the isotropy of the composite anode and improved its rate performance. Compared with SGT, the capacity retention rate of the sample (OSGT-50%OHSC) after oxidation - pyrolysis at a high current density of 5.0 A g-1 increased from 7.2% to 25.8%. Additionally, the PEA/PVP artificial SEI strengthened the cycle stability of the anode. After 1000 cycles, the capacity retention rate increased from 22.5% to 70.3%. The artificial SEI effectively avoided direct contact between the anode and the electrolyte, increasing the initial coulombic efficiency from 70.3% to 77.1%.
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各向同性结构和聚合物界面强化了球形石墨尾矿/焦炭复合负极中的锂离子传输
球形石墨尾矿(SGT)作为锂离子电池的负极电极,不仅提高了固体废弃物 SGT 的利用价值,而且与人造石墨相比,还证明了天然鳞片石墨(NG)的清洁生产。然而,由于各向异性结构和固体电解质界面(SEI)的不稳定性,SGT 阳极在速率性能和循环稳定性方面存在问题。在这项工作中,通过对高硫煤(HSC)和 SGT 进行造粒,制备了具有各向同性结构的复合阳极,同时利用聚醚胺/聚乙烯吡咯烷酮(PEA/PVP)交联聚合物制备了人工 SEI。结果表明,HSC 高温分解产生的焦炭增强了复合阳极的各向同性,提高了其速率性能。与 SGT 相比,样品(OSGT-50%OHSC)在 5.0 A g-1 的高电流密度下氧化-热解后的容量保持率从 7.2% 提高到 25.8%。此外,PEA/PVP 人工 SEI 还增强了阳极的循环稳定性。循环 1000 次后,容量保持率从 22.5% 提高到 70.3%。人工 SEI 有效地避免了阳极与电解质之间的直接接触,将初始库仑效率从 70.3% 提高到 77.1%。
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