光催化
纳米尺度
材料科学
电场
纳米技术
析氧
降级(电信)
吸附
氧气
表面工程
化学工程
光伏
工作(物理)
化学物理
可见光谱
静电
载流子
光电化学
催化作用
纳米-
钨
电荷
分解水
表面电荷
光电子学
工作职能
科技与社会
作者
Liang Ma,Siyuan Zhang,Haining Liu,Chunyan Wang,Zhongmei Song,Wenjie Han,Mingzhe Dong,Jungang Hou,Weidong Shi,Xiushen Ye
标识
DOI:10.1038/s41467-025-66466-5
摘要
Abstract Breaking the limitations of conventional defect engineering, this work pioneers region-specific dual-defect engineering in Bi 2 WO 6 . By precisely tailoring tungsten (W) and oxygen (O) vacancies at nanoscale spatial domains-W vacancies at the edges and O vacancies at the center-a spatially asymmetric defect configuration is achieved. This configuration induces a synergistic “defect dipole” effect, amplifying the internal electric field by 2.74 times while simultaneously enriching surface-active sites. As a result, the photocatalytic efficiency is dramatically enhanced, achieving complete oxidation of recalcitrant flotation agents-octadecylamine (ODA) and 4-dodecylmorpholine (DMP)-within just 2 h of visible light irradiation, which is 3.6 times faster than that of pristine Bi 2 WO 6 . Additionally, the generation of reactive species ( $$\cdot {{\rm{O}}}_{2}^{-}$$ ⋅ O 2 − , $${}^{1}{\rm{O}}_{2}$$ O 2 1 , and h⁺) is significantly boosted by factors of 8.98, 5.55, and 20.02, respectively, highlighting the material’s remarkable reactivity. Photoelectrochemical analyses reveal a remarkable 290% increase in charge separation efficiency. This enhancement is further supported by an improved O 2 adsorption capacity, which promotes the formation of reactive oxygen species involved in the degradation process. Impressively, the engineered Bi₂W₁₋ₓO₆₋ᵧ exhibits outstanding performance in real-world industrial wastewater treatment under solar irradiation, demonstrating its practical viability. Overall, this work establishes a new paradigm in photocatalysis by integrating precise nanoscale defect engineering with enhanced electrostatic modulation.
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