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隔膜对锂-铜电池短路时间的影响
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作者 向甜琦 鲍晋珍 +6 位作者 闫晓清 庄志 董畅 谢鹏程 刘凤泉 周建军 李林 《高分子学报》 SCIE CAS CSCD 北大核心 2023年第5期655-664,共10页
隔膜在锂离子电池中起着防止正负极直接短路和提供离子传输通道的作用,决定着电池的安全性能.在本文中,我们利用锂-铜电池的短路时间建立了一种评价隔膜安全性能的方法.通过对电池短路时间的研究发现,对于同一种类型的隔膜,短路时间与... 隔膜在锂离子电池中起着防止正负极直接短路和提供离子传输通道的作用,决定着电池的安全性能.在本文中,我们利用锂-铜电池的短路时间建立了一种评价隔膜安全性能的方法.通过对电池短路时间的研究发现,对于同一种类型的隔膜,短路时间与隔膜厚度和内阻的线性相关度较高,隔膜厚度和内阻的增加均能延长电池的短路时间.同一厚度不同类型的隔膜,其电池的短路时间与隔膜自身的微孔结构相关.电池的短路时间与隔膜的穿刺强度之间的线性相关程度较低,结合电池短路后隔膜表面枝晶形貌的观察,我们推测枝晶是沿隔膜的孔道持续生长最终穿透隔膜,而非刺穿隔膜导致的电池短路.利用不同厚度的隔膜组装锂硫电池,发现循环寿命与隔膜厚度具有显著线性相关性,验证了测试方法在实际电池使用中的有效性.同时,研究也证实,利用功能隔膜调控锂的沉积行为、抑制锂的枝晶沉积能极大延长电池的短路时间,提升电池的安全性能,这为新型高安全性复合隔膜及电池的研究和设计提供了新的思路和理论依据. 展开更多
关键词 锂金属电池 短路时间 功能复合隔膜 安全性
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Tailoring the electronic conductivity of high-loading cathode electrodes for practical sulfide-based all-solid-state batteries
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作者 Huaqing Shen Shenghao Jing +6 位作者 Siliang Liu Yuting Huang Fangbo He Yang Liu zhi zhuang Zongliang Zhang Fangyang Liu 《Advanced Powder Materials》 2023年第4期63-72,共10页
Sulfide-based all-solid-state batteries(ASSBs)exhibit unparalleled application value due to the high ionic conductivity and good processability of sulfide solid electrolytes(SSEs).Carbon-based conductive agents(CAs)are ... Sulfide-based all-solid-state batteries(ASSBs)exhibit unparalleled application value due to the high ionic conductivity and good processability of sulfide solid electrolytes(SSEs).Carbon-based conductive agents(CAs)are often used in the construction of electronic conductive networks to achieve rapid electron transfer.However,CAs accelerate the formation of decomposition products of SSEs,and their effects on sulfide-based ASSBs are not fully understood.Herein,the effect of CAs(super P,vaper-grown carbonfibers,and carbon nanotubes)on the performance of sulfide-based ASSBs is investigated under different cathode active materials mass loading(8 and 25 mg⋅cm^(-2)).The results show that under low mass loading,the side reaction between the CAs and the SSEs deteriorates the performance of the cell,while the charge transfer promotion caused by the addition of CAs is only manifested under high mass loading.Furthermore,the gradient design strategy(enrichment of CAs near the current collector side and depletion of CAs near the electrolyte side)is applied to maximize the benefits of CAs in electron transport and reduce the adverse effects of CAs.The charge carrier transport barrier inside the high mass loading electrode is significantly reduced through the regulation of electronic conductivity.Consequently,the optimized electrode achieves a high areal capacity of 5.6 mAh⋅cm^(-2)at high current density(1.25 mA⋅cm2,0.2℃)at 25℃with a capacity retention of 87.85%after 100 cycles.This work provides a promising way for the design of high-mass loading electrodes with practical application value. 展开更多
关键词 All-solid-state-batteries Conductive agents Sulfide electrolytes High mass loading Gradient designing
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