Performance of UV/acetylacetone process for saline dye wastewater treatment: Kinetics and mechanism

Fei Yang; Bo Sheng; Zhaohui Wang; Ying Xue; Jianshe Liu; Tianyi Ma; Richard Bush; Hrvoje Kušić; Yanbo Zhou

doi:10.1016/j.jhazmat.2020.124774

Performance of UV/acetylacetone process for saline dye wastewater treatment: Kinetics and mechanism

Fei Yang
, Bo Sheng
, Zhaohui Wang^*
, Ying Xue
, Jianshe Liu
, Tianyi Ma
, Richard Bush
, Hrvoje Kušić
, Yanbo Zhou

^*此作品的通讯作者

生态与环境科学学院

Donghua University
University of Newcastle
Ministry of Natural Resources of the People's Republic of China
Shanghai Engineering Research Center of Biotransformation of Organic Solid Waste
Tongji University
Monash University
University of Zagreb
East China University of Science and Technology

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28 引用（Scopus）

摘要

Futility of traditional advanced oxidation processes (AOPs) in saline wastewater treatment has stimulated the quest for novel “halotolerant” chemical oxidation technology. Acetylacetone (AA) has proven to be a potent photo-activator in the degradation of dyes, but the applicability of UV/AA for saline wastewater treatment needs to be verified. In this study, degradation of crystal violet (CV) was investigated in the UV/AA system in the presence of various concentrations of exogenic Cl^- or Br^-. The results reveal that degradation, mineralization and even accumulation of adsorbable organic halides (AOX) were not significantly affected by the addition of Cl^- or Br^-. Rates of CV degradation were enhanced by elevating either AA dosage or solution acidity. An apparent kinetic rate equation was developed as r = -d[CV]/dt = k[CV]^a[AA]^b = (7.34 × 10^-4 mM^1-(a+b) min^-1) × [CV]^a=0.16 [AA]^b=0.97. In terms of results of radical quenching experiments, direct electron/energy transfer is considered as the major reaction mechanism, while either singlet oxygen or triplet state (³(AA)*) might be involved. Based on identification of degradation byproducts, a possible degradation pathway of CV in the UV/AA system is proposed.

源语言	英语
文章编号	124774
期刊	Journal of Hazardous Materials
卷	406
DOI	https://doi.org/10.1016/j.jhazmat.2020.124774
出版状态	已出版 - 15 3月 2021

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@article{208ef863e69342f6b8c6416f313c07be,

title = "Performance of UV/acetylacetone process for saline dye wastewater treatment: Kinetics and mechanism",

abstract = "Futility of traditional advanced oxidation processes (AOPs) in saline wastewater treatment has stimulated the quest for novel “halotolerant” chemical oxidation technology. Acetylacetone (AA) has proven to be a potent photo-activator in the degradation of dyes, but the applicability of UV/AA for saline wastewater treatment needs to be verified. In this study, degradation of crystal violet (CV) was investigated in the UV/AA system in the presence of various concentrations of exogenic Cl- or Br-. The results reveal that degradation, mineralization and even accumulation of adsorbable organic halides (AOX) were not significantly affected by the addition of Cl- or Br-. Rates of CV degradation were enhanced by elevating either AA dosage or solution acidity. An apparent kinetic rate equation was developed as r = -d[CV]/dt = k[CV]a[AA]b = (7.34 × 10-4 mM1-(a+b) min-1) × [CV]a=0.16 [AA]b=0.97. In terms of results of radical quenching experiments, direct electron/energy transfer is considered as the major reaction mechanism, while either singlet oxygen or triplet state (3(AA)*) might be involved. Based on identification of degradation byproducts, a possible degradation pathway of CV in the UV/AA system is proposed.",

keywords = "AOX formation, Degradation pathway, Mineralization, Reaction orders, Singlet oxygen",

author = "Fei Yang and Bo Sheng and Zhaohui Wang and Ying Xue and Jianshe Liu and Tianyi Ma and Richard Bush and Hrvoje Ku{\v s}i{\'c} and Yanbo Zhou",

note = "Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",

year = "2021",

month = mar,

day = "15",

doi = "10.1016/j.jhazmat.2020.124774",

language = "英语",

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T1 - Performance of UV/acetylacetone process for saline dye wastewater treatment

T2 - Kinetics and mechanism

AU - Yang, Fei

AU - Sheng, Bo

AU - Wang, Zhaohui

AU - Xue, Ying

AU - Liu, Jianshe

AU - Ma, Tianyi

AU - Bush, Richard

AU - Kušić, Hrvoje

AU - Zhou, Yanbo

PY - 2021/3/15

Y1 - 2021/3/15

N2 - Futility of traditional advanced oxidation processes (AOPs) in saline wastewater treatment has stimulated the quest for novel “halotolerant” chemical oxidation technology. Acetylacetone (AA) has proven to be a potent photo-activator in the degradation of dyes, but the applicability of UV/AA for saline wastewater treatment needs to be verified. In this study, degradation of crystal violet (CV) was investigated in the UV/AA system in the presence of various concentrations of exogenic Cl- or Br-. The results reveal that degradation, mineralization and even accumulation of adsorbable organic halides (AOX) were not significantly affected by the addition of Cl- or Br-. Rates of CV degradation were enhanced by elevating either AA dosage or solution acidity. An apparent kinetic rate equation was developed as r = -d[CV]/dt = k[CV]a[AA]b = (7.34 × 10-4 mM1-(a+b) min-1) × [CV]a=0.16 [AA]b=0.97. In terms of results of radical quenching experiments, direct electron/energy transfer is considered as the major reaction mechanism, while either singlet oxygen or triplet state (3(AA)*) might be involved. Based on identification of degradation byproducts, a possible degradation pathway of CV in the UV/AA system is proposed.

AB - Futility of traditional advanced oxidation processes (AOPs) in saline wastewater treatment has stimulated the quest for novel “halotolerant” chemical oxidation technology. Acetylacetone (AA) has proven to be a potent photo-activator in the degradation of dyes, but the applicability of UV/AA for saline wastewater treatment needs to be verified. In this study, degradation of crystal violet (CV) was investigated in the UV/AA system in the presence of various concentrations of exogenic Cl- or Br-. The results reveal that degradation, mineralization and even accumulation of adsorbable organic halides (AOX) were not significantly affected by the addition of Cl- or Br-. Rates of CV degradation were enhanced by elevating either AA dosage or solution acidity. An apparent kinetic rate equation was developed as r = -d[CV]/dt = k[CV]a[AA]b = (7.34 × 10-4 mM1-(a+b) min-1) × [CV]a=0.16 [AA]b=0.97. In terms of results of radical quenching experiments, direct electron/energy transfer is considered as the major reaction mechanism, while either singlet oxygen or triplet state (3(AA)*) might be involved. Based on identification of degradation byproducts, a possible degradation pathway of CV in the UV/AA system is proposed.

KW - AOX formation

KW - Degradation pathway

KW - Mineralization

KW - Reaction orders

KW - Singlet oxygen

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DO - 10.1016/j.jhazmat.2020.124774

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JO - Journal of Hazardous Materials

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ER -

Performance of UV/acetylacetone process for saline dye wastewater treatment: Kinetics and mechanism

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