Aqueous batteries are an emerging next-generation technology for large-scale energy storage.Among various metal-ion systems,manganese-based batteries have attracted significant interest due to their superior theoretic...Aqueous batteries are an emerging next-generation technology for large-scale energy storage.Among various metal-ion systems,manganese-based batteries have attracted significant interest due to their superior theoretical energy density over zinc-based battery systems.This study demonstrates oxygen vacancy-engineered vanadium oxide(V_(2)O_(4.85))as a high-performance cathode material for aqueous manganese metal batteries.The V_(2)O_(4.85) cathode had a discharge capacity of 212.6 mAh g^(-1) at 0.1 A g^(-1),retaining 89.5%capacity after 500 cycles.Oxygen vacancies enhanced ion diffusion and reduced migration barriers,facilitating both Mn^(2+)and H^(+)ion intercalation.Proton intercalation dominated charge storage,forming Mn(OH)_(2) layers,whereas Mn^(2+)contributed to surface-limited reactions.Furthermore,manganese metal batteries had a significantly higher operating voltage than that of aqueous zinc battery systems.Despite challenges with hydrogen evolution reactions at the Mn metal anode,this study underscores the potential of manganese batteries for future energy storage systems.展开更多
Aqueous batteries with metal anodes exhibit robust anodic capacities,but their energy densities are low because of the limited potential stabilities of aqueous electrolyte solutions.Current metal options,such as Zn an...Aqueous batteries with metal anodes exhibit robust anodic capacities,but their energy densities are low because of the limited potential stabilities of aqueous electrolyte solutions.Current metal options,such as Zn and Al,pose a dilemma:Zn lacks a sufficiently low redox potential,whereas Al tends to be strongly oxidized in aqueous environments.Our investigation introduces a novel rechargeable aqueous battery system based on Mn as the anode.We examine the effects of anions,electrolyte concentration,and diverse cathode chemistries.Notably,the ClO_(4)-based electrolyte solution exhibits improved deposition and dissolution efficiencies.Although stainless steel(SS 316 L)and Ni are stable current collectors for cathodes,they display limitations as anodes.However,using Ti as the anode resulted in increased Mn deposition and dissolution efficiencies.Moreover,we evaluate this system using various cathode materials,including Mn-intercalation-based inorganic(Ag0.33V2O5)and organic(perylenetetracarboxylic dianhydride)cathodes and an anionintercalation-chemistry(coronene)-based cathode.These configurations yield markedly higher output potentials compared to those of Zn metal batteries,highlighting the potential for an augmented energy density when using an Mn anode.This study outlines a systematic approach for use in optimizing metal anodes in Mn metal batteries,unlocking novel prospects for Mn-based batteries with diverse cathode chemistries.展开更多
Magnesium-ion batteries(MIBs)are promising candidates for lithium-ion batteries because of their abundance,non-toxicity,and favorable electrochemical properties.This review explores the reaction mechanisms and electro...Magnesium-ion batteries(MIBs)are promising candidates for lithium-ion batteries because of their abundance,non-toxicity,and favorable electrochemical properties.This review explores the reaction mechanisms and electrochemical characteristics of Mg-alloy anode materials.While Mg metal anodes provide high volumetric capacity and dendrite-free electrodeposition,their practical application is hindered by challenges such as sluggish Mg^(2+)ion diffusion and electrolyte compatibility.Alloy-type anodes that incorporate groups XIII,XIV,and XV elements have the potential to overcome these limitations.We review various Mg alloys,emphasizing their alloying/dealloying reaction mechanisms,their theoretical capacities,and the practical aspects of MIBs.Furthermore,we discuss the influence of the electrolyte composition on the reversibility and efficiency of these alloy anodes.Emphasis is placed on overcoming current limitations through innovative materials and structural engineering.This review concludes with perspectives on future research directions aimed at enhancing the performance and commercial viability of Mg alloy anodes and contributing to the development of high-capacity,safe,and cost-effective energy storage systems.展开更多
基金supported by the Global Joint Research Program funded by Pukyong National University(202411790001)supported by the Nano&Material Technology Development Program through the National Research Foundation of Korea(NRF),funded by the Ministry of Science and ICT(RS-2024-00446825)by the Technology Innovation Program(RS-2024-00418815)funded by the Ministry of Trade,Industry&Energy(MOTIE,Korea).
文摘Aqueous batteries are an emerging next-generation technology for large-scale energy storage.Among various metal-ion systems,manganese-based batteries have attracted significant interest due to their superior theoretical energy density over zinc-based battery systems.This study demonstrates oxygen vacancy-engineered vanadium oxide(V_(2)O_(4.85))as a high-performance cathode material for aqueous manganese metal batteries.The V_(2)O_(4.85) cathode had a discharge capacity of 212.6 mAh g^(-1) at 0.1 A g^(-1),retaining 89.5%capacity after 500 cycles.Oxygen vacancies enhanced ion diffusion and reduced migration barriers,facilitating both Mn^(2+)and H^(+)ion intercalation.Proton intercalation dominated charge storage,forming Mn(OH)_(2) layers,whereas Mn^(2+)contributed to surface-limited reactions.Furthermore,manganese metal batteries had a significantly higher operating voltage than that of aqueous zinc battery systems.Despite challenges with hydrogen evolution reactions at the Mn metal anode,this study underscores the potential of manganese batteries for future energy storage systems.
基金supported by the Global Joint Research Program funded by the Pukyong National University(202411790001)。
文摘Aqueous batteries with metal anodes exhibit robust anodic capacities,but their energy densities are low because of the limited potential stabilities of aqueous electrolyte solutions.Current metal options,such as Zn and Al,pose a dilemma:Zn lacks a sufficiently low redox potential,whereas Al tends to be strongly oxidized in aqueous environments.Our investigation introduces a novel rechargeable aqueous battery system based on Mn as the anode.We examine the effects of anions,electrolyte concentration,and diverse cathode chemistries.Notably,the ClO_(4)-based electrolyte solution exhibits improved deposition and dissolution efficiencies.Although stainless steel(SS 316 L)and Ni are stable current collectors for cathodes,they display limitations as anodes.However,using Ti as the anode resulted in increased Mn deposition and dissolution efficiencies.Moreover,we evaluate this system using various cathode materials,including Mn-intercalation-based inorganic(Ag0.33V2O5)and organic(perylenetetracarboxylic dianhydride)cathodes and an anionintercalation-chemistry(coronene)-based cathode.These configurations yield markedly higher output potentials compared to those of Zn metal batteries,highlighting the potential for an augmented energy density when using an Mn anode.This study outlines a systematic approach for use in optimizing metal anodes in Mn metal batteries,unlocking novel prospects for Mn-based batteries with diverse cathode chemistries.
基金supported by the Global Joint Research Program funded by the Pukyong National University(202411790001).
文摘Magnesium-ion batteries(MIBs)are promising candidates for lithium-ion batteries because of their abundance,non-toxicity,and favorable electrochemical properties.This review explores the reaction mechanisms and electrochemical characteristics of Mg-alloy anode materials.While Mg metal anodes provide high volumetric capacity and dendrite-free electrodeposition,their practical application is hindered by challenges such as sluggish Mg^(2+)ion diffusion and electrolyte compatibility.Alloy-type anodes that incorporate groups XIII,XIV,and XV elements have the potential to overcome these limitations.We review various Mg alloys,emphasizing their alloying/dealloying reaction mechanisms,their theoretical capacities,and the practical aspects of MIBs.Furthermore,we discuss the influence of the electrolyte composition on the reversibility and efficiency of these alloy anodes.Emphasis is placed on overcoming current limitations through innovative materials and structural engineering.This review concludes with perspectives on future research directions aimed at enhancing the performance and commercial viability of Mg alloy anodes and contributing to the development of high-capacity,safe,and cost-effective energy storage systems.
