Solar‐powered semiconductor photocatalysis is considered a powerful strategy for addressing environmental pollution and energy crisis.Nevertheless,the separation and transfer abilities of photogenerated photocatalyst...Solar‐powered semiconductor photocatalysis is considered a powerful strategy for addressing environmental pollution and energy crisis.Nevertheless,the separation and transfer abilities of photogenerated photocatalysts remain unsatisfactory.Herein,dual Ti_(3)C_(2)nanosheets/Ag co‐catalysts synergistically decorated hierarchical flower‐like TiO_(2)microspheres for boosting photocatalytic H_(2)production were fabricated by electrostatic self‐assembly and subsequent photoreduction procedures.The optimal Ag/Ti_(3)C_(2)/TiO_(2)composite demonstrated an excellent photocatalytic H_(2)‐production rate of 1024.72μmol g^(−1)h^(−1)under simulated solar irradiation,achieving nearly 40,2.3,and 1.8 folds with respect to that obtained on pristine TiO2,optimized Ti_(3)C_(2)/TiO_(2)composite,and Ag/TiO_(2)composite,respectively.The considerably improved photocatalytic H_(2)‐production activity is associated with the synergistic effect of the hierarchical flower‐like structure of TiO2,excellent electrical conductivity of Ti_(3)C_(2),and surface plasmon resonance effect of Ag,which enhances the light absorption capacity and promotes the separation and transfer of photogenerated carriers.This study provides insight into the design of high‐efficiency photocatalysts with dual co‐catalysts for solar H_(2)production.展开更多
We report a successful tuning of the hole doping level over a wide range in high temperature superconductor Bi2Sr2CaCu2O8+δ (Bi2212) through successive in situ potassium (K) deposition. By taking high resolution...We report a successful tuning of the hole doping level over a wide range in high temperature superconductor Bi2Sr2CaCu2O8+δ (Bi2212) through successive in situ potassium (K) deposition. By taking high resolution angleresolved photoemission measurements on the Fermi surface and band structure of an overdoped Bi2212 (To = 76 K) at different stages of K deposition, we found that the area of the hole-like Fermi surface around the Brillouin zone corner (n,n) shrinks with increasing K deposition. This indicates a continuous hole concentration change from initial - 0.26 to eventual 0.09 after extensive K deposition, a net doping level change of 0.17 that makes it possible to bring Bi2212 from being originally overdoped, to optimally-doped, and even- tually becoming heavily underdoped. The electronic behaviors with K deposition are consistent with those of Bi2212 samples with different hole doping levels. These results demonstrate that K deposition is an effective way of in situ controlling the hole concentration in Bi2212. This work opens a good way of studying the doping evolution of electronic structure and establishing the electronic phase diagram in Bi2212 that can be extended to other cuprate superconductors.展开更多
文摘Solar‐powered semiconductor photocatalysis is considered a powerful strategy for addressing environmental pollution and energy crisis.Nevertheless,the separation and transfer abilities of photogenerated photocatalysts remain unsatisfactory.Herein,dual Ti_(3)C_(2)nanosheets/Ag co‐catalysts synergistically decorated hierarchical flower‐like TiO_(2)microspheres for boosting photocatalytic H_(2)production were fabricated by electrostatic self‐assembly and subsequent photoreduction procedures.The optimal Ag/Ti_(3)C_(2)/TiO_(2)composite demonstrated an excellent photocatalytic H_(2)‐production rate of 1024.72μmol g^(−1)h^(−1)under simulated solar irradiation,achieving nearly 40,2.3,and 1.8 folds with respect to that obtained on pristine TiO2,optimized Ti_(3)C_(2)/TiO_(2)composite,and Ag/TiO_(2)composite,respectively.The considerably improved photocatalytic H_(2)‐production activity is associated with the synergistic effect of the hierarchical flower‐like structure of TiO2,excellent electrical conductivity of Ti_(3)C_(2),and surface plasmon resonance effect of Ag,which enhances the light absorption capacity and promotes the separation and transfer of photogenerated carriers.This study provides insight into the design of high‐efficiency photocatalysts with dual co‐catalysts for solar H_(2)production.
基金XJZ thanks financial support from the National Natural Science foundation of China (11190022,11334010 and 11534007)the National Basic Research Program of China (2015CB921000)the Strategic Priority Research Program (B) of Chinese Academy of Sciences (XDB07020300)
文摘We report a successful tuning of the hole doping level over a wide range in high temperature superconductor Bi2Sr2CaCu2O8+δ (Bi2212) through successive in situ potassium (K) deposition. By taking high resolution angleresolved photoemission measurements on the Fermi surface and band structure of an overdoped Bi2212 (To = 76 K) at different stages of K deposition, we found that the area of the hole-like Fermi surface around the Brillouin zone corner (n,n) shrinks with increasing K deposition. This indicates a continuous hole concentration change from initial - 0.26 to eventual 0.09 after extensive K deposition, a net doping level change of 0.17 that makes it possible to bring Bi2212 from being originally overdoped, to optimally-doped, and even- tually becoming heavily underdoped. The electronic behaviors with K deposition are consistent with those of Bi2212 samples with different hole doping levels. These results demonstrate that K deposition is an effective way of in situ controlling the hole concentration in Bi2212. This work opens a good way of studying the doping evolution of electronic structure and establishing the electronic phase diagram in Bi2212 that can be extended to other cuprate superconductors.
