DOI: 10.1016/j.watres.2018.10.028
Scopus记录号: 2-s2.0-85054834968
论文题名: Photoreactivation of fungal spores in water following UV disinfection and their control using UV-based advanced oxidation processes
作者: Wen G. ; Deng X. ; Wan Q. ; Xu X. ; Huang T.
刊名: Water Research
ISSN: 431354
出版年: 2019
卷: 148 起始页码: 1
结束页码: 9
语种: 英语
英文关键词: Control
; Dark repair
; Fungal spores
; Photoreactivation
; UV-Based advanced oxidation processes
Scopus关键词: Aspergillus
; Control engineering
; Disinfection
; Escherichia coli
; Groundwater
; Oxidation
; Rate constants
; Repair
; Advanced oxidation process
; Advanced Oxidation Processes
; After-treatment
; Aspergillus niger
; First-order models
; Fungal spores
; Photoreactivation
; Trichoderma harzianum
; Water treatment
; fungal DNA
; ground water
; hydrogen peroxide
; biochemical composition
; disinfection
; fungus
; oxidation
; photochemistry
; spore
; ultraviolet radiation
; water pollution
; Article
; Aspergillus niger
; cell membrane
; darkness
; disinfection
; Escherichia coli
; fungal cell
; fungal cell wall
; fungus spore
; Hypocrea lixii
; light intensity
; oxidation
; Penicillium
; Penicillium polonicum
; photoreactivation
; ultraviolet A radiation
; waste water management
; water sampling
; Aspergillus niger
; Bacteria (microorganisms)
; Fungi
; Hypocrea lixii
; Penicillium polonicum
英文摘要: The occurrence of repair system in microorganisms after ultraviolet (UV)-induced damage to them evokes concern regarding the effectiveness of UV disinfection. Most studies focus on the repair of bacteria, but little research has been conducted on the repair of fungi in water. This study aimed to investigate the photoreactivation and dark repair properties of three dominant genera of fungal spores (Trichoderma harzianum, Aspergillus niger, and Penicillium polonicum) isolated from groundwater. UV-based advanced oxidation processes (AOPs) (including UV/peroxymonosulfate and UV/hydrogen peroxide) were used to control their photoreactivation. The results demonstrated that the three genera of fungal spores inactivated by UV (254 nm) exhibited different levels of photoreactivation under UVA (365 nm) exposure, and the photoreactivation percentage showed that T. harzianum (51.35%) >A. niger (29.07%) >P. polonicum (9.01%). The photoreactivation process of fungal spores was well described by the first-order model. T. harzianum had lower photoreactivation percentage but a more rapid initial photoreactivation process than E. coli. Higher UV dosages significantly decreased the photoreactivation percentage of fungal spores. However, dark repair was insignificant following UV disinfection for all the three genera of fungal spores. After treatment by UV-based AOPs, the fungal spores exhibited the same photoreactivation trend as those treated by UV alone. However, both the maximum survival ratios and photoreactivation rate constants were reduced to varying degrees. This study revealed the photoreactivation rule of dominant genera of fungi isolated from groundwater following UV treatment alone and UV-based AOPs, which is effective for controlling fungi in water. © 2018 Elsevier Ltd Citation statistics:
资源类型: 期刊论文
标识符: http://119.78.100.158/handle/2HF3EXSE/122233
Appears in Collections: 气候变化事实与影响
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作者单位: Key Laboratory of Northwest Water Resource, Environment and Ecology, MOE, Xi'an University of Architecture and Technology, Xi'an, 710055, China; Shaanxi Key Laboratory of Environmental Engineering, Xi'an University of Architecture and Technology, Xi'an, 710055, China
Recommended Citation:
Wen G.,Deng X.,Wan Q.,et al. Photoreactivation of fungal spores in water following UV disinfection and their control using UV-based advanced oxidation processes[J]. Water Research,2019-01-01,148