The limited redox capability of photocatalysts often leads to harmful NO_(2) byproduct formation during photocatalytic NO oxidation.Herein,Bi_(4)Ti_(3)O_(12) nanosheets modified with plasmonic metallic bismuth and abu...The limited redox capability of photocatalysts often leads to harmful NO_(2) byproduct formation during photocatalytic NO oxidation.Herein,Bi_(4)Ti_(3)O_(12) nanosheets modified with plasmonic metallic bismuth and abundant oxygen vacancies were synthesized via an in-situ reduction method.The optimized catalyst(BTOR2,with a molar ratio of 40%NaBH_(4) to Bi_(4)Ti_(3)O_(12))achieved a maximum NO removal efficiency of 62.3%,significantly higher than pristine Bi_(4)Ti_(3)O_(12)(40.5%) while minimizing NO_(2) production.The results reveal that the synergistic effects of Bi’s plasmonic resonance and oxygen vacancies enhanced visible light absorption and charge separation.The density functional theory(DFT)analysis showed electrons can transfer from Bi_(4)Ti_(3)O_(12)to Bi,promoting O_(2)activation to·O_(2)^(-)radicals.In-situ diffuse reflectance infrared Fourier transform spectroscopy(DRIFTS)confirmed that light-induced H2O adsorption was strengthened,improving·OH radical generation.These radicals promoted the selective conversion of activated NO^(-) to NO_(3)^(-),rather than NO_(2).This work provides valuable insights for advancing research into efficient photocatalysts for air pollution control.展开更多
Solid-state sodium batteries(SSSBs)have been highly prized as a promising alternative to conventional battery systems using organic liquid electrolytes due to their improved safety,higher energy density,and substantia...Solid-state sodium batteries(SSSBs)have been highly prized as a promising alternative to conventional battery systems using organic liquid electrolytes due to their improved safety,higher energy density,and substantial resources and low cost of sodium.Na_(3)Zr_(2)Si_(2)PO_(12)(NZSP)solid electrolyte is attracting considerable interest owing to its excellent thermal and chemical stability and favorable compatibility with Na metal anode and high-voltage cathode.However,two main challenges of poor roomtemperature ionic conductivity and high interfacial resistance limit the application of NZSP electrolyte in SSSBs.So far,intensive efforts have been devoted to developing modification strategies to improve the room-temperature ionic conductivity of NZSP.This review aims to provide a comprehensive summary and discussion of some optimization strategies for enhancing the room-temperature ionic conductivity of the NZSP solid electrolyte.These optimization strategies are categorized into foreignion doping or substitution,sintering behavior modulation,and regulation of chemical composition based on precursors,and their optimization mechanisms are also elaborated.Finally,the prospects of NZSP-based solid electrolytes are presented.This review is expected to offer better guidance for designing and developing high-performance NZSP-based solid electrolytes for accelerating the practical application of SSSBs.展开更多
基金supported by the Natural Science Foundation of Chongqing(Nos.CSTB2024NSCQ-MSX1278,CSTB2023NSCQ-MSX0006)Technology Innovation Project of Shapingba District,Chongqing(No.2024004)+2 种基金Science and Technology Research Program of Chongqing Municipal Education Commission(Nos.KJZD-K202403102,KJQN202103110,KJQN202400512,KJQN202403107)National Natural Science Foundation of China(No.22406014)China Postdoctoral Science Foundation(No.2023MD744137).
文摘The limited redox capability of photocatalysts often leads to harmful NO_(2) byproduct formation during photocatalytic NO oxidation.Herein,Bi_(4)Ti_(3)O_(12) nanosheets modified with plasmonic metallic bismuth and abundant oxygen vacancies were synthesized via an in-situ reduction method.The optimized catalyst(BTOR2,with a molar ratio of 40%NaBH_(4) to Bi_(4)Ti_(3)O_(12))achieved a maximum NO removal efficiency of 62.3%,significantly higher than pristine Bi_(4)Ti_(3)O_(12)(40.5%) while minimizing NO_(2) production.The results reveal that the synergistic effects of Bi’s plasmonic resonance and oxygen vacancies enhanced visible light absorption and charge separation.The density functional theory(DFT)analysis showed electrons can transfer from Bi_(4)Ti_(3)O_(12)to Bi,promoting O_(2)activation to·O_(2)^(-)radicals.In-situ diffuse reflectance infrared Fourier transform spectroscopy(DRIFTS)confirmed that light-induced H2O adsorption was strengthened,improving·OH radical generation.These radicals promoted the selective conversion of activated NO^(-) to NO_(3)^(-),rather than NO_(2).This work provides valuable insights for advancing research into efficient photocatalysts for air pollution control.
基金National Natural Science Foundation of China,Grant/Award Number:52272225。
文摘Solid-state sodium batteries(SSSBs)have been highly prized as a promising alternative to conventional battery systems using organic liquid electrolytes due to their improved safety,higher energy density,and substantial resources and low cost of sodium.Na_(3)Zr_(2)Si_(2)PO_(12)(NZSP)solid electrolyte is attracting considerable interest owing to its excellent thermal and chemical stability and favorable compatibility with Na metal anode and high-voltage cathode.However,two main challenges of poor roomtemperature ionic conductivity and high interfacial resistance limit the application of NZSP electrolyte in SSSBs.So far,intensive efforts have been devoted to developing modification strategies to improve the room-temperature ionic conductivity of NZSP.This review aims to provide a comprehensive summary and discussion of some optimization strategies for enhancing the room-temperature ionic conductivity of the NZSP solid electrolyte.These optimization strategies are categorized into foreignion doping or substitution,sintering behavior modulation,and regulation of chemical composition based on precursors,and their optimization mechanisms are also elaborated.Finally,the prospects of NZSP-based solid electrolytes are presented.This review is expected to offer better guidance for designing and developing high-performance NZSP-based solid electrolytes for accelerating the practical application of SSSBs.
