Constructing electrode materials with large capacity and good conductivity is an effective approach to improve the capacitor performance of asymmetric supercapacitors(ASCs).In this paper,ZnCo_(2)S_(4)core-shell nanosp...Constructing electrode materials with large capacity and good conductivity is an effective approach to improve the capacitor performance of asymmetric supercapacitors(ASCs).In this paper,ZnCo_(2)S_(4)core-shell nanospheres are constructed by two-step hydrothermal method.In order to improve the chemical activity of ZnCo_(2)S_(4),ZnCo_(2)S_(4)is activated using cetyltrimethylammonium bromide(CTAB).Then,MXene nanosheets are fixed on the surface of ZnCo_(2)S_(4)by electrostatic selfassembly method to improve the specific surface area of ZnCo_(2)S_(4)and MXene-wrapped ZnCo_(2)S_(4)composite is prepared in this work.Owing to the synergy effect between MXene nanosheets and ZnCo_(2)S_(4)core-shell nanospheres,the as-prepared composite displays fast ion transfer rate and charge/discharge process.The capacity of the MXenewrapped ZnCo_(2)S_(4)composite can reach 1072 F·g^(-1),which is far larger than that of ZnCo_(2)S_(4)(407 F·g^(-1))at 1 A·g^(-1).An ASC device is assembled,which delivers 1.7 V potential window and superior cyclic stability(95.41%capacitance retention).Furthermore,energy density of this device is up to 30.46 Wh·kg^(-1)at a power density of850 W·kg^(-1).The above results demonstrate that MXenewrapped ZnCo_(2)S_(4)composite has great application prospects in electrochemical energy storage field.展开更多
Composites derived from metal-organic frameworks(MOFs)show promise as catalysts for the photocat-alytic reduction of CO_(2).However,their potential is hindered by constraints such as limited light absorp-tion and slug...Composites derived from metal-organic frameworks(MOFs)show promise as catalysts for the photocat-alytic reduction of CO_(2).However,their potential is hindered by constraints such as limited light absorp-tion and sluggish electron transfer and separation,impacting the overall efficiency of the photocatalytic process.In this study,TiO_(2)nanocrystals,modified with Ptx+,underwent laser etching were encapsulated within the traditional MOF-ZIF-8 framework.This enhanced the adsorption capabilities for CO_(2)reactants and solar light,while also facilitating directed electron transfer and the separation of photogenerated charges.The finely-tuned catalyst demonstrates impressive CH_(4) selectivity at 9.5%,with yields of 250.24μmol g^(-1)h^(-1)for CO and 25.43μmol g^(-1)h^(-1)for CH_(4),utilizing water as a hole trap and H^(+)source.This study demonstrates the viability of achieving characteristics related to the separation of photogen-erated charges in TiO_(2)nanocrystals through laser etching and MOF composite catalysts.It offers novel perspectives for designing MOF-based catalysts with enhanced performance in artificial photosynthesis.展开更多
基金financially supported by the Fundamental Research Funds for the Central Universities (No. 2019XKQYMS16)
文摘Constructing electrode materials with large capacity and good conductivity is an effective approach to improve the capacitor performance of asymmetric supercapacitors(ASCs).In this paper,ZnCo_(2)S_(4)core-shell nanospheres are constructed by two-step hydrothermal method.In order to improve the chemical activity of ZnCo_(2)S_(4),ZnCo_(2)S_(4)is activated using cetyltrimethylammonium bromide(CTAB).Then,MXene nanosheets are fixed on the surface of ZnCo_(2)S_(4)by electrostatic selfassembly method to improve the specific surface area of ZnCo_(2)S_(4)and MXene-wrapped ZnCo_(2)S_(4)composite is prepared in this work.Owing to the synergy effect between MXene nanosheets and ZnCo_(2)S_(4)core-shell nanospheres,the as-prepared composite displays fast ion transfer rate and charge/discharge process.The capacity of the MXenewrapped ZnCo_(2)S_(4)composite can reach 1072 F·g^(-1),which is far larger than that of ZnCo_(2)S_(4)(407 F·g^(-1))at 1 A·g^(-1).An ASC device is assembled,which delivers 1.7 V potential window and superior cyclic stability(95.41%capacitance retention).Furthermore,energy density of this device is up to 30.46 Wh·kg^(-1)at a power density of850 W·kg^(-1).The above results demonstrate that MXenewrapped ZnCo_(2)S_(4)composite has great application prospects in electrochemical energy storage field.
文摘Composites derived from metal-organic frameworks(MOFs)show promise as catalysts for the photocat-alytic reduction of CO_(2).However,their potential is hindered by constraints such as limited light absorp-tion and sluggish electron transfer and separation,impacting the overall efficiency of the photocatalytic process.In this study,TiO_(2)nanocrystals,modified with Ptx+,underwent laser etching were encapsulated within the traditional MOF-ZIF-8 framework.This enhanced the adsorption capabilities for CO_(2)reactants and solar light,while also facilitating directed electron transfer and the separation of photogenerated charges.The finely-tuned catalyst demonstrates impressive CH_(4) selectivity at 9.5%,with yields of 250.24μmol g^(-1)h^(-1)for CO and 25.43μmol g^(-1)h^(-1)for CH_(4),utilizing water as a hole trap and H^(+)source.This study demonstrates the viability of achieving characteristics related to the separation of photogen-erated charges in TiO_(2)nanocrystals through laser etching and MOF composite catalysts.It offers novel perspectives for designing MOF-based catalysts with enhanced performance in artificial photosynthesis.
