Pt nanocluster-Fe single atom pairs dual-regulate charge extraction and interfacial reaction for enhanced photoelectric response
Yuanxing Chen, Ying Qin, Mingwang Liu, Wenhong Yang, Yiwei Qiu, Wen J. Li, Lirong Zheng, Wenling Gu, Chengzhou Zhu, Liuyong Hu
Abstract
Energy level mismatches between semiconductors and cocatalysts often induce carrier recombination, limiting photocatalytic and photoelectrochemical (PEC) efficiency. Here, we integrate Pt nanocluster-Fe single-atom pairs with CuO to regulate both solid-solid and solid-liquid interfaces in PEC systems. Experimental and theoretical analyses reveal that an Ohmic contact at the CuO/Pt interface accelerates electron extraction, while Pt-to-Fe charge transfer enhances oxygen reduction at Fe sites, collectively boosting reaction kinetics. Leveraging this, we construct a PEC biosensor exploiting chelating effect of glyphosate on CuO to impede electron transfer, achieving a detection limit of 0.41 ng/mL. This interface engineering strategy advances cocatalyst design for enhanced energy conversion and sensing applications by simultaneously addressing carrier dynamics and interfacial reaction barriers. Efficient electron extraction in photoelectrocatalysts requires matching energy levels between semiconductors and catalysts. Here, the authors show this matching enhances electron extraction from copper oxide by combining platinum nanoclusters and iron single-atom catalysts.