Sodium metal batteries(SMBs)are rising as viable alternatives to lithium-ion systems due to their superior energy density and sodium's relative abundance.However,SMBs face significant impediments,particularly the ...Sodium metal batteries(SMBs)are rising as viable alternatives to lithium-ion systems due to their superior energy density and sodium's relative abundance.However,SMBs face significant impediments,particularly the exceedingly high negative-to-positive capacity ratios(N/P ratios)which severely encumber energy density and hinder their practical application.Herein,a novel nucleophilic Na_(3)P interphase on aluminum foil has been designed to significantly lower the nucleation energy barrier for sodium atom deposition,resulting in a remarkable reduction of nucleation overpotential and efficient mitigation of dendritic growth at high sodium deposition of 5 mA h cm^(−2).The interphase promotes stable cycling in anode-less SMB configurations with a low N/P ratio of 1.4 and high cathode mass loading of 11.5 mg cm^(−2),and demonstrates a substantial increase in high capacity retention of 92.4%after 500 cycles even under 1 C rate condition.This innovation signifies a promising leap forward in the development of high-energy-density,anode-less SMBs,offering a potential solution to the longstanding issues of cycle stability and energy efficiency.展开更多
While all-solid-state batteries have built global consensus with regard to their impact in safety and energy density,their anode-less versions have attracted appreciable attention because of the possibility of further...While all-solid-state batteries have built global consensus with regard to their impact in safety and energy density,their anode-less versions have attracted appreciable attention because of the possibility of further lowering the cell volume and cost.This perspective article summarizes recent research trends in anode-less all-solid-state batteries(ALASSBs)based on different types of solid electrolytes and anticipates future directions these batteries may take.We particularly aim to motivate researchers in the field to challenge remaining issues in ALASSBs by employing advanced materials and cell designs.展开更多
Electrolytes make up a large portion of the volume of energy storage devices,but they often do not contribute to energy storage.The ability of using electrolytes to store charge would promise a significant increase in...Electrolytes make up a large portion of the volume of energy storage devices,but they often do not contribute to energy storage.The ability of using electrolytes to store charge would promise a significant increase in energy density to meet the needs of evolving electronic devices.Redox-flow batteries use electrolytes to store energy and show high energy densities,but the same design cannot be applied to portable or microdevices that require static electrolytes.Therefore,implementing electrolyte energy storage in a non-flow design becomes critical.This review summarizes the requirements for a stable and efficient electrolyte and diverse redox-active species dissolved in aqueous solutions.More importantly,we review the pioneering works using static electrolyte energy storage in the hope that it will pave a new way to design compact and energy-dense batteries.展开更多
基金funding support from the National Natural Science Foundation of China (22125902, 22109150, 22279126, U2032202, and 21975243)the DNL cooperation Fund, CAS (DNL202020)+1 种基金the National Key R&D Program of China (no. 2022YFA1504101)the Anhui Provincial Natural Science Foundation (2108085QB65)
文摘Sodium metal batteries(SMBs)are rising as viable alternatives to lithium-ion systems due to their superior energy density and sodium's relative abundance.However,SMBs face significant impediments,particularly the exceedingly high negative-to-positive capacity ratios(N/P ratios)which severely encumber energy density and hinder their practical application.Herein,a novel nucleophilic Na_(3)P interphase on aluminum foil has been designed to significantly lower the nucleation energy barrier for sodium atom deposition,resulting in a remarkable reduction of nucleation overpotential and efficient mitigation of dendritic growth at high sodium deposition of 5 mA h cm^(−2).The interphase promotes stable cycling in anode-less SMB configurations with a low N/P ratio of 1.4 and high cathode mass loading of 11.5 mg cm^(−2),and demonstrates a substantial increase in high capacity retention of 92.4%after 500 cycles even under 1 C rate condition.This innovation signifies a promising leap forward in the development of high-energy-density,anode-less SMBs,offering a potential solution to the longstanding issues of cycle stability and energy efficiency.
基金support from the Swiss National Science Foundation(SNF)(Grant No.Sinergia CRSII5_202296)the National Research Foundation of Korea(NRF)(Grant No.NRF-2022M3J1A1054151)+1 种基金generous support from the Institute of Engineering Research(IOER)Research Institute of Advanced Materials(RIAM)at Seoul National University.
文摘While all-solid-state batteries have built global consensus with regard to their impact in safety and energy density,their anode-less versions have attracted appreciable attention because of the possibility of further lowering the cell volume and cost.This perspective article summarizes recent research trends in anode-less all-solid-state batteries(ALASSBs)based on different types of solid electrolytes and anticipates future directions these batteries may take.We particularly aim to motivate researchers in the field to challenge remaining issues in ALASSBs by employing advanced materials and cell designs.
基金M Zhu acknowledges the support by the German Research Foundation DFG(ZH 989/2-1)O G Schmidt acknowledges financial support by the Leibniz Program of the German Research Foundation(SCHM 1298/26-1)H Tang,Z Qu,W Zhang and H Zhang acknowledge the support and funding from China Scholarship Council(CSC).
文摘Electrolytes make up a large portion of the volume of energy storage devices,but they often do not contribute to energy storage.The ability of using electrolytes to store charge would promise a significant increase in energy density to meet the needs of evolving electronic devices.Redox-flow batteries use electrolytes to store energy and show high energy densities,but the same design cannot be applied to portable or microdevices that require static electrolytes.Therefore,implementing electrolyte energy storage in a non-flow design becomes critical.This review summarizes the requirements for a stable and efficient electrolyte and diverse redox-active species dissolved in aqueous solutions.More importantly,we review the pioneering works using static electrolyte energy storage in the hope that it will pave a new way to design compact and energy-dense batteries.
