@article{c983448a53fa4cf388581ccbaefc0266,
title = "Nanoscale colocalization of fluorogenic probes reveals the role of oxygen vacancies in the photocatalytic activity of tungsten oxide nanowires",
abstract = "Defect engineering is a strategy that has been widely used to design active semiconductor photocatalysts. However, understanding the role of defects, such as oxygen vacancies, in controlling photocatalytic activity remains a challenge. Here, we report the use of chemically triggered fluorogenic probes to study the spatial distribution of active regions in individual tungsten oxide nanowires using super-resolution fluorescence microscopy. The nanowires show significant heterogeneity along their lengths for the photocatalytic generation of hydroxyl radicals. Through quantitative, coordinate-based colocalization of multiple probe molecules activated by the same nanowires, we demonstrate that the nanoscale regions most active for the photocatalytic generation of hydroxyl radicals also possess a greater concentration of oxygen vacancies. Chemical modifications to remove or block access to surface oxygen vacancies, supported by calculations of binding energies of adsorbates to different surface sites on tungsten oxide, show how these defects control catalytic activity at both the ensemble and single-particle levels. These findings reveal that clusters of oxygen vacancies activate surface-adsorbed water molecules toward photo-oxidation to produce hydroxyl radicals, a critical intermediate in several photocatalytic reactions.",
keywords = "Colocalization, Fluorescence, Oxygen vacancies, Single-molecule localization microscopy, Tungsten oxide",
author = "Meikun Shen and Tianben Ding and Hartman, {Steven T.} and Fudong Wang and Christina Krucylak and Zheyu Wang and Che Tan and Bo Yin and Rohan Mishra and Lew, {Matthew D.} and Bryce Sadtler",
note = "Funding Information: This material is based on work supported by the National Science Foundation under grant no. CHE-1753344 to B.S. and under grant no. ECCS-1653777 to M.D.L. Acknowledgment is made to the donors of the American Chemical Society Petroleum Research Fund for partial support of this research (award #PRF58165-DNI10). B.S. and M.D.L acknowledge support from the International Center for Energy, Environment and Sustainability (InCEES) at Washington University. Computational resources were provided by the Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by NSF grants ACI-1053575 and ACI-1548562. S.T.H. and R.M. acknowledge support from the NSF under grant no. DMREF CBET-1729787. Electron microscopy and X-ray photoelectron spectroscopy were performed at the Institute of Materials Science & Engineering at Washington University. X-ray diffraction was performed in the Department of Earth and Planetary Sciences at Washington University. Zeta potential measurements were performed at the Nano Research Facility at Washington University. The authors thank S. Singamaneni for the use of his Raman spectrometer, B. Wieliczka and R. Loomis for the use of their absorption spectrometer, J. Lu for the helpful discussion, and O. Zhang for the technical assistance. Publisher Copyright: {\textcopyright} 2020 American Chemical Society.",
year = "2020",
month = feb,
day = "7",
doi = "10.1021/acscatal.9b04481",
language = "English",
volume = "10",
pages = "2088--2099",
journal = "ACS Catalysis",
issn = "2155-5435",
number = "3",
}