CdS-Cu1.81S heteronanorods with continuous sublattice for photocatalytic hydrogen production

“…53 Besides, the heterojunction can accelerate the charge transfer and reflect the change in current response in the transient photocurrent spectrum. 54 These photoelectrochemical results confirm that the separation and transfer of photogenerated charge of ZIS/ ZnS-2 heterojunction photocatalyst have been improved, thus ensuring a significant improvement in the performance of photocatalytic hydrogen evolution.…”

A Z-scheme ZnIn₂S₄/ZnS heterojunction catalyst: insight into enhanced photocatalytic performance and mechanism

“…53 Besides, the heterojunction can accelerate the charge transfer and reflect the change in current response in the transient photocurrent spectrum. 54 These photoelectrochemical results confirm that the separation and transfer of photogenerated charge of ZIS/ ZnS-2 heterojunction photocatalyst have been improved, thus ensuring a significant improvement in the performance of photocatalytic hydrogen evolution.…”

A Z-scheme ZnIn₂S₄/ZnS heterojunction catalyst: insight into enhanced photocatalytic performance and mechanism

“…The obtained partial CE product Cu 2− x S/CdS is an important material for photocatalysis, which is capable of visible-light and infrared light-active photocatalytic H 2 generation with superior efficiency and stability. 16,76–78…”

Crystal structure dependent cation exchange reactions in Cu_2−xS nanoparticles

“…For pristine CdS, two peaks at 405 eV and 411.77 eV are attributed to the binding energy of Cd 3d 5/2 and Cd 3d 3/2 of Cd(II), while two peaks of S 2p 3/2 and S 2p 1/2 are observed at 161.55 eV and 162.75 eV, respectively, indicating the chemical state of S is À2. 35,36 For Bi 2 Se 3 /CdS in Fig. 3a and b, these two peaks of Cd 3d at 404.85 eV and 411.62 eV have an obvious shift to lower energy by about 0.15 eV.…”

Ultrathin Bi₂Se₃/CdS composite for efficient photocatalytic hydrogen evolutionviahigh interfacial charge separation and photothermal effect