Significant progress has been made in developing advanced materials for energy storage and conversion,with lithium-ion batteries(LIBs)remaining a dominant technology.While graphite has long been the standard anode mat...Significant progress has been made in developing advanced materials for energy storage and conversion,with lithium-ion batteries(LIBs)remaining a dominant technology.While graphite has long been the standard anode material,its limited theoretical capacity and poor rate capability pose challenges such as shorter battery life and prolonged charging times.To address these limitations,molybdenum disulfide(MoS_(2)),a layered transition metal sulfide,has emerged as a promising alternative due to its much higher theoretical capacity and potential to enable more energy-dense and durable batteries.Despite its promise,MoS_(2)-based LIBs face critical challenges,including low electrical conductivity,substantial volume changes during lithiation and delithiation,and scalability issues in material synthesis.Ensuring structural stability and compatibility with electrolytes further complicates its practical application.Addressing these issues is essential to unlock the full potential of MoS_(2)as a high-performance anode material.Current research has explored strategies such as doping and defect engineering to improve electrical conductivity and enhance overall electrochemical performance.Furthermore,composite designs have demonstrated synergistic effects that not only improve electrical conductivity but also promote efficient lithium-ion transport,contributing to enhanced rate capability and cycling stability.This review comprehensively examines the progress,challenges,and innovative strategies associated with MoS_(2)-based anode materials for LIBs.Finally,it provides insights into future perspectives,focusing on the development and application of MoS_(2)to advance next-generation energy storage technologies.展开更多
Widespread volcanism associated with Middle Triassic carbonate platforms is well known,and in many cases referred as a partial cause of the disruption of platform development due to burial by volcanic material.It is n...Widespread volcanism associated with Middle Triassic carbonate platforms is well known,and in many cases referred as a partial cause of the disruption of platform development due to burial by volcanic material.It is no doubt that silicic explosive volcanism produced large volume of volcanic material accumulated in basins surrounding the carbonate platforms(Buchenstein basins)alternating with pelagic carbonates of basin facies.There are large numbers of mafic eruptive products associated with individual carbonate platforms such as the Latemar in the Dolomites in northern Italy.展开更多
基金supported by research fund of Chungnam National University.
文摘Significant progress has been made in developing advanced materials for energy storage and conversion,with lithium-ion batteries(LIBs)remaining a dominant technology.While graphite has long been the standard anode material,its limited theoretical capacity and poor rate capability pose challenges such as shorter battery life and prolonged charging times.To address these limitations,molybdenum disulfide(MoS_(2)),a layered transition metal sulfide,has emerged as a promising alternative due to its much higher theoretical capacity and potential to enable more energy-dense and durable batteries.Despite its promise,MoS_(2)-based LIBs face critical challenges,including low electrical conductivity,substantial volume changes during lithiation and delithiation,and scalability issues in material synthesis.Ensuring structural stability and compatibility with electrolytes further complicates its practical application.Addressing these issues is essential to unlock the full potential of MoS_(2)as a high-performance anode material.Current research has explored strategies such as doping and defect engineering to improve electrical conductivity and enhance overall electrochemical performance.Furthermore,composite designs have demonstrated synergistic effects that not only improve electrical conductivity but also promote efficient lithium-ion transport,contributing to enhanced rate capability and cycling stability.This review comprehensively examines the progress,challenges,and innovative strategies associated with MoS_(2)-based anode materials for LIBs.Finally,it provides insights into future perspectives,focusing on the development and application of MoS_(2)to advance next-generation energy storage technologies.
基金Project supported by the Hungarian Research Found(OTKA T043341 BT)NZ-FRST Post-doctoral Fellowship(MAUX 405)(KN)and Massey University Research Fund(KN)Constructive reviews by Corina Risso(Buenos Aires)and Peter Suhr(Dresden)significantly elevated the quality of this report,many thanks for them.
文摘Widespread volcanism associated with Middle Triassic carbonate platforms is well known,and in many cases referred as a partial cause of the disruption of platform development due to burial by volcanic material.It is no doubt that silicic explosive volcanism produced large volume of volcanic material accumulated in basins surrounding the carbonate platforms(Buchenstein basins)alternating with pelagic carbonates of basin facies.There are large numbers of mafic eruptive products associated with individual carbonate platforms such as the Latemar in the Dolomites in northern Italy.
