Abstract
Aiming to achieve enhanced photocatalytic activity and stability toward the generation of H2
from water, we have synthesized noble metal-free core-shell nanoparticles of graphene (G)-wrapped
CdS and TiO2 (CdS@G@TiO2) by a facile hydrothermal method. The interlayer thickness of G
between the CdS core and TiO2 shell is optimized by varying the amount of graphene quantum dots
(GQD) during the synthesis procedure. The most optimized sample, i.e., CdS@50G@TiO2 generated
1510 µmole g−1 h
−1 of H2 (apparent quantum efficiency (AQE) = 5.78%) from water under simulated
solar light with air mass 1.5 global (AM 1.5G) condition which is ~2.7 times and ~2.2 time superior to
pure TiO2 and pure CdS respectively, along with a stable generation of H2 during 40 h of continuous
operation. The increased photocatalytic activity and stability of the CdS@50G@TiO2 sample are
attributed to the enhanced visible light absorption and efficient charge separation and transfer
between the CdS and TiO2 due to incorporation of graphene between the CdS core and TiO2 shell,
which was also confirmed by UV-vis, photoelectrochemical and valence band XPS measurements
from water, we have synthesized noble metal-free core-shell nanoparticles of graphene (G)-wrapped
CdS and TiO2 (CdS@G@TiO2) by a facile hydrothermal method. The interlayer thickness of G
between the CdS core and TiO2 shell is optimized by varying the amount of graphene quantum dots
(GQD) during the synthesis procedure. The most optimized sample, i.e., CdS@50G@TiO2 generated
1510 µmole g−1 h
−1 of H2 (apparent quantum efficiency (AQE) = 5.78%) from water under simulated
solar light with air mass 1.5 global (AM 1.5G) condition which is ~2.7 times and ~2.2 time superior to
pure TiO2 and pure CdS respectively, along with a stable generation of H2 during 40 h of continuous
operation. The increased photocatalytic activity and stability of the CdS@50G@TiO2 sample are
attributed to the enhanced visible light absorption and efficient charge separation and transfer
between the CdS and TiO2 due to incorporation of graphene between the CdS core and TiO2 shell,
which was also confirmed by UV-vis, photoelectrochemical and valence band XPS measurements