The in situ construction of ZnIn₂S₄/CdIn₂S₄ 2D/3D nano hetero-structure for an enhanced visible-light-driven hydrogen production

Abstract: Through in-situ modification of CdIn2S4 nano-octahedron on the surface of ZnIn2S4 nanosheets, ZnIn2S4/CdIn2S4 nano-composites with tight interface contact are obtained by one-step solvothermal method. Due to ZnIn2S4/CdIn2S4 nano-heterostructure, the optimized...

“…[ 22 , 23 , 24 ] In addition, ultrathin 2D nanosheet structures of ZIS not only possess a high specific surface area but also shorten the diffusion distance of charge carriers to the abundance of exposed active sites. [ 25 ] However, the excessive self‐assembly and aggregation of 2D ultrathin ZIS nanosheets greatly reduce its number of active sites and block photogenerated carrier separation, which severely restricts its photocatalytic activity. [ 26 ] In general, pristine ZIS weakly adsorbs visible light; thus, it has a narrow solar light response range and poor charge separation/transfer efficiency.…”

One‐Step MOF‐Templated Strategy to Fabrication of Ce‐Doped ZnIn₂S₄ Tetrakaidecahedron Hollow Nanocages as an Efficient Photocatalyst for Hydrogen Evolution

“…[ 22 , 23 , 24 ] In addition, ultrathin 2D nanosheet structures of ZIS not only possess a high specific surface area but also shorten the diffusion distance of charge carriers to the abundance of exposed active sites. [ 25 ] However, the excessive self‐assembly and aggregation of 2D ultrathin ZIS nanosheets greatly reduce its number of active sites and block photogenerated carrier separation, which severely restricts its photocatalytic activity. [ 26 ] In general, pristine ZIS weakly adsorbs visible light; thus, it has a narrow solar light response range and poor charge separation/transfer efficiency.…”

One‐Step MOF‐Templated Strategy to Fabrication of Ce‐Doped ZnIn₂S₄ Tetrakaidecahedron Hollow Nanocages as an Efficient Photocatalyst for Hydrogen Evolution

“…), which possess desirable characteristics, such as adjustable direct band gap and wide optical absorption range, representing a family of visible light-responsive photocatalysts with promising performances for H 2 evolution. 8–12 On the other hand, their photocatalytic activity is limited by the high bulk recombination of photogenerated charge carriers and the deficiency of active sites. In this regard, the state-of-the-art approach to boost the photocatalytic performance is constructing TMC-based hybrid photocatalyst systems.…”

Self-assembled transition metal chalcogenides@CoAl-LDH 2D/2D heterostructures with enhanced photoactivity for hydrogen evolution

“…As a popular II–III 2 –VI 4 ternary chalcogenide semiconductor, because of adjustable shape, strong light absorption, suitable bandgap and excellent chemical stability, ZnIn 2 S 4 (ZIS) has attracted much attention in the field of photocatalytic hydrogen evolution [12] . The photocatalytic hydrogen evolution of bare ZIS, however, has a low H 2 conversion efficiency due to a paucity of catalytic active sites and the carriers′ high recombination efficiency [13–15] . As a result, several attempts have been undertaken to improve the photocatalytic hydrogen evolution of ZIS in order to improve carrier usage efficiency and prevent charge recombination.…”

“…[12] The photocatalytic hydrogen evolution of bare ZIS, however, has a low H 2 conversion efficiency due to a paucity of catalytic active sites and the carriers' high recombination efficiency. [13][14][15] As a result, several attempts have been undertaken to improve the photocatalytic hydrogen evolution of ZIS in order to improve carrier usage efficiency and prevent charge recombination. such as element doping, cocatalyst modifying, noble mental deposition, constructing heterojunctions, and so on.…”

Fast Interlayer Charge Separation and Transmission in ZnIn₂S₄/CNTs/ZnS Heterojunctions for Efficient Photocatalytic Hydrogen Evolution