Abstract
C3N4 is a promising visible-light-driven photocatalyst with superior chemical stability and photostability. The intrinsic problem associated with its use is that recombination of photogenerated electron-hole pairs slows down the industrial process. We designed novel C3N4/CdS/MoS2 sandwich hybrids to increase the carrier utilization efficiency according to well-matched band alignment. The smart arrangement of C3N4-CdS-MoS2 led to step-by-step electron/hole pair separation. Meanwhile, the conductive layer MoS2 supported the easy surface transfer of electrons. The higher coefficient of separation and transfer results in a more effective reduction of electron/hole pair recombination compared to previous work. The Rhodamine B (RhB) photodegradation rate constant for the hybrids is considerably enhanced compared to pure C3N4, from 0.0309 to 0.0533 min−1. The strategy of loading separation/transfer bifunctional cocatalysts can be widely used to maximize the solar utilization efficiency of other photocatalysts.
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