Sulfide solid electrolytes with an ultrahigh ionic conductivity are considered to be extremely promising alternatives to liquid electrolytes for next-generation lithium batteries.However,it is difficult to obtain a th...Sulfide solid electrolytes with an ultrahigh ionic conductivity are considered to be extremely promising alternatives to liquid electrolytes for next-generation lithium batteries.However,it is difficult to obtain a thin solid electrolyte layer with good mechanical properties due to the weak binding ability between their powder particles,which seriously limits the actual energy density of sulfide all-solid-state lithium batteries(ASSLBs).Fortunately,the preparation of sulfide-polymer composite solid electrolyte(SPCSE)membranes by introducing polymer effectively reduces the thickness of solid electrolytes and guarantees high mechanical properties.In this review,recent progress of SPCSE membranes for ASSLBs is summarized.The classification of components in SPCSE membranes is first introduced briefly.Then,the preparation methods of SPCSE membranes are categorized according to process characteristics,in which the challenges of different methods and their corresponding solutions are carefully reviewed.The energy densities of the full battery composed of SPCSE membranes are further given whenever available to help understanding the device-level performance.Finally,we discuss the potential challenges and research opportunities for SPCSE membranes to guide the future development of high-performance sulfide ASSLBs.展开更多
FeS_(2)cathode is promising for all-solid-state lithium batteries due to its ultra-high capacity,low cost,and environmental friendliness.However,the poor performances,induced by limited electrode-electrolyte interface...FeS_(2)cathode is promising for all-solid-state lithium batteries due to its ultra-high capacity,low cost,and environmental friendliness.However,the poor performances,induced by limited electrode-electrolyte interface,severe volume expansion,and polysulfide shuttle,hinder the application of FeS_(2)in all-solid-state lithium batteries.Herein,an integrated 3D FeS_(2)electrode with full infiltration of Li6PS5Cl sulfide electrolytes is designed to address these challenges.Such a 3D integrated design not only achieves intimate and maximized interfacial contact between electrode and sulfide electrolytes,but also effectively buffers the inner volume change of FeS_(2)and completely eliminates the polysulfide shuttle through direct solid-solid conversion of Li2S/S.Besides,the vertical 3D arrays guarantee direct electron transport channels and horizontally shortened ion diffusion paths,endowing the integrated electrode with a remarkably reduced interfacial impedance and enhanced reaction kinetics.Benefiting from these synergies,the integrated all-solid-state lithium battery exhibits the largest reversible capacity(667 mAh g^(-1)),best rate performance,and highest capacity retention of 82%over 500 cycles at 0.1 C compared to both a liquid battery and non-integrated all-solid-state lithium battery.The cycling performance is among the best reported for FeS_(2)-based all-solid-state lithium batteries.This work presents an innovative synergistic strategy for designing long-cycling high-energy all-solid-state lithium batteries,which can be readily applied to other battery systems,such as lithium-sulfur batteries.展开更多
基金supported by grants from the National Natural Science Foundation of China(Nos.52072136,52172229,52272201,52302303,51972257)Yanchang Petroleum-WHUT Joint Program(No.yc-whlg-2022ky-05)Fundamental Research Funds for the Central Universities(Nos.104972024RSCrc0006,2023IVA106)for financial support。
文摘Sulfide solid electrolytes with an ultrahigh ionic conductivity are considered to be extremely promising alternatives to liquid electrolytes for next-generation lithium batteries.However,it is difficult to obtain a thin solid electrolyte layer with good mechanical properties due to the weak binding ability between their powder particles,which seriously limits the actual energy density of sulfide all-solid-state lithium batteries(ASSLBs).Fortunately,the preparation of sulfide-polymer composite solid electrolyte(SPCSE)membranes by introducing polymer effectively reduces the thickness of solid electrolytes and guarantees high mechanical properties.In this review,recent progress of SPCSE membranes for ASSLBs is summarized.The classification of components in SPCSE membranes is first introduced briefly.Then,the preparation methods of SPCSE membranes are categorized according to process characteristics,in which the challenges of different methods and their corresponding solutions are carefully reviewed.The energy densities of the full battery composed of SPCSE membranes are further given whenever available to help understanding the device-level performance.Finally,we discuss the potential challenges and research opportunities for SPCSE membranes to guide the future development of high-performance sulfide ASSLBs.
基金supported by the National Natural Science Foundation of China(Grant nos.52272201,52072136,52172229,52302303,and 51972257)Yanchang Petroleum-WHUT Joint Program(yc-whlg-2022ky-05)+1 种基金the State Key Laboratory of Advanced Technology for Materials Synthesis and Processing(Wuhan University of Technology,2022-KF-20)Fundamental Research Funds for the Central Universities(2023IVA106)for financial support
文摘FeS_(2)cathode is promising for all-solid-state lithium batteries due to its ultra-high capacity,low cost,and environmental friendliness.However,the poor performances,induced by limited electrode-electrolyte interface,severe volume expansion,and polysulfide shuttle,hinder the application of FeS_(2)in all-solid-state lithium batteries.Herein,an integrated 3D FeS_(2)electrode with full infiltration of Li6PS5Cl sulfide electrolytes is designed to address these challenges.Such a 3D integrated design not only achieves intimate and maximized interfacial contact between electrode and sulfide electrolytes,but also effectively buffers the inner volume change of FeS_(2)and completely eliminates the polysulfide shuttle through direct solid-solid conversion of Li2S/S.Besides,the vertical 3D arrays guarantee direct electron transport channels and horizontally shortened ion diffusion paths,endowing the integrated electrode with a remarkably reduced interfacial impedance and enhanced reaction kinetics.Benefiting from these synergies,the integrated all-solid-state lithium battery exhibits the largest reversible capacity(667 mAh g^(-1)),best rate performance,and highest capacity retention of 82%over 500 cycles at 0.1 C compared to both a liquid battery and non-integrated all-solid-state lithium battery.The cycling performance is among the best reported for FeS_(2)-based all-solid-state lithium batteries.This work presents an innovative synergistic strategy for designing long-cycling high-energy all-solid-state lithium batteries,which can be readily applied to other battery systems,such as lithium-sulfur batteries.
