ISSN: 0256-1115 (print version) ISSN: 1975-7220 (electronic version)
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English
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In relation to this article, we declare that there is no conflict of interest.
Publication history
Received September 9, 2025
Revised February 20, 2026
Accepted March 8, 2026
Available online June 26, 2026
articles This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/bync/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
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Most Cited

Cooperative oxidation/reduction of pesticides in water by vacuum ultraviolet: the dual role of dissolved oxygen

School of Physical Education, Shaoyang University 1School of Food and Chemical Engineering, Shaoyang University
y366001031@126.com
Korean Journal of Chemical Engineering, June 2026, 43(8), 2243-2253(11)
https://doi.org/10.1007/s11814-026-00703-5

Abstract

Persistent pesticides pose significant environmental and health risks due to their resistance to conventional water treatment

methods. This study explores the cooperative oxidation and reduction of two typical pesticides, namely atrazine 

(ATZ) and lindane (LND), under vacuum ultraviolet (VUV) irradiation, with a particular focus on the dual role of dissolved

oxygen (DO) in modulating degradation mechanisms and kinetics. In oxygen-deprived conditions, VUV irradiation 

achieved 92.9% ATZ removal with minimal TOC reduction (<5%), whereas the introduction of 10 mg L–1 DO enhanced 

ATZ mineralization to 67.1% by sustaining hydroxyl radical (HO•

) concentrations. Conversely, DO presence reduced LND 

degradation efficiency from 86.5% to 46.6% by scavenging solvated electrons (eaq–

), yet improved TOC removal from 

4.8% to 26.7% through enhanced oxidative transformation of intermediates. ATZ undergoes hydroxyl radical-mediated 

oxidation, while LND degradation is driven by solvated electrons-initiated reduction. A competition kinetics model was 

employed to determine the second-order rate constants of reactive species, revealing that HO•

 plays a dominant role in 

ATZ degradation (kATZ,HO• =2.5×109

 M–1S–1) and eaq–

 is primarily responsible for LND decomposition (kLND,eaq−

=1.0×1010 M–1S–1). Numerous degradation byproducts were identified by GC-MS, revealing three pathways for ATZ 

and multiple reductive routes for LND. These findings highlight the intricate interplay between oxidative and reductive 

mechanisms mediated by DO, emphasizing the necessity of controlling oxygen levels for efficient pollutant degradation 

and comprehensive mineralization.

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