« Previous AbstractPrecise preparation of biomass-based porous carbon with pore structure-dependent VOCs adsorption/desorption performance by bacterial pretreatment and its forming process    Next Abstract"Selection Behavior and OBP-Transcription Response of Western Flower Thrips, Frankliniella occidentalis, to Six Plant VOCs from Kidney Beans" »

Environ Technol

Title:		Research on the kinetics and degradation pathways of gaseous acetic acid ester organics
Author(s):		Wang Y; Wei J; Hu J; Guo Z; Bai W;
Address:		"Institute of Atomic and Molecular Physics, Sichuan University, Chengdu, People's Republic of China. Sichuan Profit Energy Technology Co., Ltd, Chengdu, People's Republic of China"
Journal Title:		Environ Technol
Year:		2023
Volume:		20230319
Issue:
Page Number:		1 - 14
DOI:		10.1080/09593330.2023.2185819
ISSN/ISBN:		1479-487X (Electronic) 0959-3330 (Linking)
Abstract:		"ABSTRACTDesigned to meet the specific needs of the printing industry exhaust gas emissions, this paper proposes a method for the degradation of gaseous acetic acid ester organics that is environmentally friendly, safe, and simple to use: micro-nano cavitation technology. In the process of using micro-nano cavitation technology to degrade acetic acid ester organics, the products in the degradation process were analyzed by gas chromatography-mass (GC-MS) spectrometry, and the degradation pathways of acetic acid ester organics were identified. Under high temperatures and high pressure caused by cavitation collapse, the C-C bond and C-O bond on the main chain of organic matter are cleaved to form low molecular products. Low-molecular intermediate products are continuously produced as the reaction advances, and these intermediate products are further oxidized and decomposed into carbon dioxide and water. Besides, the factors that influence the degradation rate of acetic acid ester organics were investigated. Based on the experimental data, acetic acid esters can degrade with the greatest efficiency when their initial concentration is 200 +/- 50 mg/m(3) and their treatment time is 20 approximately 30 min. Moreover, the experiment was optimized using the response surface method. The results suggested that for an initial concentration of 155.544 mg/m(3) and a reaction time of 21.961 min, the best degradation rate was 0.251 min(-1). Micro-nano cavitation technology is a novel and promising technology for the degradation of volatile organic compounds, with a wide range of practical applications"
Keywords:		Gc-ms Micro-nano bubbles acetic acid ester cavitation degradation;
Notes:		"PublisherWang, Yulan Wei, Jianjun Hu, Juan Guo, Zhongming Bai, William eng England 2023/03/02 Environ Technol. 2023 Mar 19:1-14. doi: 10.1080/09593330.2023.2185819"