posted on 2024-10-09, 09:06authored byJieding Wei, Dian Luo, Manman Shi, Saiya Guo, Zhou Lu, Yonghong Ni
Efficient utilization of photogenerated charge carriers
to realize
photocatalytic solar fuel production and oxidative chemical synthesis
is a challenging task. Herein, a conventional amidation reaction route
is adopted to successfully construct a novel composite photocatalyst
composed of a Ni(II)–terpyridine complex with carboxyl groups
grafted on CdS nanorods (labeled as CdS@Ni(terpyC)2). Experimental
results have unequivocally revealed that the as-fabricated composite
catalyst exhibited a remarkable enhancement in photocatalytic activity
for the dehydrogenation of benzyl alcohol under visible light, demonstrating
superior hydrogen evolution efficiency and benzaldehyde selectivity,
surpassing both pristine CdS and the blend of CdS and Ni(terpyC)2. The carrier dynamics study demonstrated that the Ni(terpyC)2 on the surface of CdS could quickly extract the photogenerated
electrons of CdS, which reduced the carrier recombination efficiency,
further improving the photocatalytic activity of the catalyst. This
work illustrates the effect of surface active site engineering on
photocatalysis and is expected to shed substantial inspiration on
future surface modulation and design of semiconductor photocatalysts.