Light-driven interfaces for PFAS detection and destruction

RSC Applied Interfaces Pub Date : 2024-07-05 DOI:10.1039/D4LF00171K

Frank R. A. Schrama, Scott E. Massimi, Michael R. Dooley, Brian G. Trewyn, Shubham Vyas and Ryan M. Richards

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Abstract

Due to exposure risks and health concerns, global limitations on per- and polyfluoroalkyl substances (PFAS) have become increasingly restrictive over the last few years, with limitations of some legacy PFAS in drinking water reaching single digit ppt in the United States and certain European countries. As the allotted maxima for contamination have reached such low levels, broad research efforts in the degradation and detection of PFAS materials are being intensely investigated. Light driven technologies (photocatalysis and plasmonics) represent important interfacial phenomena with potential to detect and/or decompose PFAS. Despite the commonalities at the interface, little discussion merging detection and destruction exists, thereby resulting in minimal transference of concepts, experimental success, and potential dual functionality systems. This review will cover the basics of photocatalytic degradation technologies surrounding PFAS, the basics of plasmonics for PFAS detection, and a discussion on how these fields can progress in future work.

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用于检测和销毁全氟辛烷磺酸的光驱动界面

由于暴露风险和健康问题，过去几年来，全球对全氟烷基和多氟烷基物质（PFAS）的限制越来越严格，在美国和某些欧洲国家，饮用水中某些传统 PFAS 的限制已达到个位数 ppt。由于污染的最大值已达到如此低的水平，目前正在对全氟辛烷磺酸材料的降解和检测进行广泛的研究。光驱动技术（光催化和等离子体）是重要的界面现象，具有检测和/或分解 PFAS 的潜力。尽管在界面上存在共性，但很少有人讨论如何将检测和破坏合二为一，从而导致概念、实验成功和潜在的双重功能系统之间的交流少之又少。本综述将介绍与全氟辛烷磺酸有关的光催化降解技术的基本原理、用于全氟辛烷磺酸检测的等离子体学的基本原理，并讨论这些领域在未来的工作中如何取得进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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RSC Applied Interfaces

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