Nanometric‐Mapping and In Situ Quantification of Site‐specific Photoredox Activities on 2D Nanoplates

Nanometric‐Mapping and In Situ Quantification of Site‐specific Photoredox Activities on 2D Nanoplates

Defective layered bismuth oxychloride (BiOCl) exhibits excellent photocatalytic activities in water purification and environmental remediation. Herein, in situ single‐molecule fluorescence microscopy is used to spatially resolve the photocatalytic heterogeneity and quantify the photoredox activities...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Vol. 20; no. 45; pp. e2401120 - n/a
Main Authors: Wu, Shuyang, Lee, Jinn‐Kye, Zhang, Zhengyang
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-11-2024
Subjects:
BiOCl nanoplate
Bismuth
Crystal defects
Design optimization
facet‐dependent property
Heterogeneity
Oxidation
Photocatalysis
single‐molecule fluorescence microscopy
site‐specific photoredox activity
Steering
structure‐activity correlation
Turnover rate
Two dimensional materials
Water purification
site‐specific photoredox activity
single‐molecule fluorescence microscopy
structure‐activity correlation
facet‐dependent property
BiOCl nanoplate
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Summary:Defective layered bismuth oxychloride (BiOCl) exhibits excellent photocatalytic activities in water purification and environmental remediation. Herein, in situ single‐molecule fluorescence microscopy is used to spatially resolve the photocatalytic heterogeneity and quantify the photoredox activities on individual structural features of BiOCl. The BiOCl nanoplates with respective dominant {001} and {010} facets (BOC‐001 and BOC‐010) are fabricated through tuning the pH of the solution. The corner position of BOC‐001 exhibits the highest photo‐oxidation turnover rate of 262.7 ± 30.8 s−1 µm−2, which is 2.1 and 65.7 times of those of edges and basal planes, respectively. A similar trend is also observed on BOC‐010, which can be explained by the heterogeneous distribution of defects at each structure. Besides, BOC‐001 shows a higher photoredox activity than BOC‐010 at corners and edges. This can be attributed to the superior charge separation ability, active high‐index facets of BOC‐001, and its co‐exposure of anisotropic facets steering the charge flow. Therefore, this work provides an effective strategy to understand the facet‐dependent properties of single‐crystalline materials at nanometer resolution. The quantification of site‐specific photoredox activities on BiOCl nanoplates sheds more light on the design and optimization of 2D materials at the single‐molecule level. Single‐molecule fluorescence microscopy is employed to achieve the nanometric‐mapping of photoactive species on 2D bismuth oxychloride (BiOCl) nanoplates with distinct facets exposed. The site‐specific photoredox activities are in situ quantified at corners, edges, and basal planes of BiOCl. This study helps understand the facet‐dependent properties at the single‐molecule level and construct the “structure‐activity” correlation at the nanoscale.
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ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202401120