Br_(2)/Br^(−)is a promising redox couple in fl ow batteries because of its high potential,solubility,and low cost.However,the reaction between Br^(−)and Br_(2)only involves a single-electron transfer process,which lim...Br_(2)/Br^(−)is a promising redox couple in fl ow batteries because of its high potential,solubility,and low cost.However,the reaction between Br^(−)and Br_(2)only involves a single-electron transfer process,which limits its energy density.Herein,a novel two-electron transfer reaction based on Br^(−)/Br^(+) was studied and realized through Br^(+) intercalation into graphite to form a bromine-graphite intercalation compound(Br-GIC).Compared with the pristine Br^(−)/Br_(2)redox pair,the redox potential of Br intercalation/deintercalation in graphite is 0.5 V higher,which has the potential to substantially increase the energy density.Diff erent from Br_(2)/Br^(−)in the electrolyte,the diff usion rate of Br intercalation in graphite decreases with increasing charge state because of the decreasing intercalation sites in graphite,and the integrity of the graphite structure is important for the intercalation reaction.As a result,the battery can continuously run for more than 300 cycles with a Coulombic effi-ciency exceeding 97%and an energy effi ciency of approximately 80%at 30 mA/cm^(2),and the energy density increases by 65%compared with Br^(−)/Br_(2).Combined with double-electron transfer and a highly reversible electrochemical process,the Br intercalation redox couple demonstrates very promising prospects for stationary energy storage.展开更多
基金supported by National Natural Science Foundation of China(Nos.21935003,21925804)the Strategic Priority Research Program of the Chinese Academy of Sci-ences(No.XDA21070100)+1 种基金CAS Engineering Laboratory for Electro-chemical Energy Storage(KFJ-PTXM-027)DICP funding(DICP I202137).
文摘Br_(2)/Br^(−)is a promising redox couple in fl ow batteries because of its high potential,solubility,and low cost.However,the reaction between Br^(−)and Br_(2)only involves a single-electron transfer process,which limits its energy density.Herein,a novel two-electron transfer reaction based on Br^(−)/Br^(+) was studied and realized through Br^(+) intercalation into graphite to form a bromine-graphite intercalation compound(Br-GIC).Compared with the pristine Br^(−)/Br_(2)redox pair,the redox potential of Br intercalation/deintercalation in graphite is 0.5 V higher,which has the potential to substantially increase the energy density.Diff erent from Br_(2)/Br^(−)in the electrolyte,the diff usion rate of Br intercalation in graphite decreases with increasing charge state because of the decreasing intercalation sites in graphite,and the integrity of the graphite structure is important for the intercalation reaction.As a result,the battery can continuously run for more than 300 cycles with a Coulombic effi-ciency exceeding 97%and an energy effi ciency of approximately 80%at 30 mA/cm^(2),and the energy density increases by 65%compared with Br^(−)/Br_(2).Combined with double-electron transfer and a highly reversible electrochemical process,the Br intercalation redox couple demonstrates very promising prospects for stationary energy storage.
