|
|
|
| Research progress on physicochemical treatment of oxytetracycline wastewater |
| Fan Mingze, Xiaoshuai |
| Hebei Shengxue Dacheng Pharmaceutical Corporation Ltd., Shijiazhuang 051430, China |
|
|
|
|
Abstract Based on the analysis of the source and water quality of oxytetracycline wastewater, the physicochemical treatment methods of oxytetracycline wastewater in recent years were summarized, and their advantages and disadvantages and treatment effects were summarized. Some problems existing in the present treatment methods are discussed, and the future development and direction of oxytetracycline wastewater treatment technology were also prospected.
|
|
|
|
|
|
| [ 1 ] Hanlin Chen,Yen Ping Peng,Ku Fan Chen, et al. Rapid synthesis
of Ti-MCM-41 by microwave-assisted hydrothermal method towards photocatalytic degradation of oxytetracycline[ J ]. Journal of Environmental Sciences, 2016, 44( 6 ): 76 - 87.
[ 2 ] Zeynep Cetecioglu, Bahar Ince, Meritxell Gros, et al. Biodegrada-
tion and reversible inhibitory impact of sulfamethoxazole on the utilization of volatile fatty acids during anaerobic treatment of pharmaceutical industry wastewater[ J ]. Science of the Total Environment, 2015( 536 ): 667 - 674.
[ 3 ] Xueqing Shi, Olivier Lefebvre,Kok Kwang Ng, et al. Sequential a-
naerobic-aerobic treatment of pharmaceutical wastewater with high salinity[ J ]. Bioresource Technology, 2014( 153 ): 79 - 86.
[ 4 ] Shuai Wu, Jingmiao Zhang, Ao Xia, et al. Microalgae cultivation f-
or antibiotic oxytetracycline wastewater treatment[ J ]. Environme-
ntal Research, 2022( 214 ): 113 - 850.
[ 5 ] Feilong Zhang, Qinyan Yue, Yuan Gao, et al. Application for oxyt-
etracycline wastewater pretreatment by Fenton iron mud based cathodic-anodic-electrolysis ceramic granular fillers - ScienceDi-
rect[ J ]. Chemosphere, 2017( 123 ): 115 - 123.
[ 6 ] Sergio Santaeufemia, Enrique Torres, Roi Mera, et al. Bioremedia-
tion of oxytetracycline in seawater by living and dead biomass of the microalga Phaeodactylum tricornutum[ J ]. Journal of Hazardo-
us Materials, 2016( 320 ): 315 - 325.
[ 7 ] Yupeng He, Zhe Tian, Qizhen Yi, et al. Impact of oxytetracycline on anaerobic wastewater treatment and mitigation using enhanced hydrolysis pretreatment[ J ]. Water Research, 2020, 187( 5 ): 116 - 408.
[ 8 ] 刘江国,李杰霞,陈玉成,等. 改性玉米秸秆对土霉素的吸附研究[ J ]. 三峡环境与生态,2009,2( 6 ):28 - 30,34.
[ 9 ] 余 剑,丁 恒,张智霖,等. 改性菱角壳生物炭吸附水中土霉素性能与机理[ J ]. 中国环境科学,2021,41( 12 ):5 688 - 5 700.
[ 10 ] 汪 晶,薛祯祯,陈 飞,等. 树脂吸附法回收母液中土霉素的实验研究[ J ]. 环境科学与技术,2008,( 10 ):26 - 28.
[ 11 ] Gülsah Baskan, ünsal Ac1kel, Menderes Levent. Investigation of adsorption properties of oxytetracycline hydrochloride on magnetic zeolite/Fe3O4 particles[ J ]. Advanced Powder Technology, 2022, 33( 6 ): 103 - 600.
[ 12 ] 高 菀. ZIF-8/PSF/TPU膜光催化降解废水中土霉素的研究[ D ]. 广东工业大学,2023.
[ 13 ] 孙贤风,宋志文,姜 蔚. 高浓度土霉素废水预处理工艺的试验研究[ J ]. 四川环境,2005,( 6 ):8 - 9.
[ 14 ] Sammani Ramanayaka, Binoy Sarkar, Asitha T. Cooray, et al. Hal-
loysite nanoclay supported adsorptive removal of oxytetracycline antibiotic from aqueous media[ J ]. Journal of Hazardous Materials, 2020( 384 ): 121 - 301.
[ 15 ] Wan Aisyah Fadilah Wae Abdulkadir, Abdul Latif Ahmad, Ooi B-
oon Seng. A water-repellent PVDF-HNT membrane for high and low concentrations of oxytetracycline treatment via DCMD: An experimental investigation[ J ]. Chemical Engineering Journal, 2021( 422 ): 129 - 644.
[ 16 ] Wan Aisyah Fadilah {Wae AbdulKadir}, Abdul Latif Ahmad, Boon Seng Ooi. Hydrophobic PVDF-HNT membrane for oxytetracycline removal via DCMD: The influence of fabrication parameters on permeability, selectivity and antifouling properties[ J ]. Journal of Water Process Engineering, 2022( 49 ): 102 - 960.
[ 17 ] Jiaxin Guo, Luca Fortunato, Bhaskar Jyoti Deka, et al. Elucidating the fouling mechanism in pharmaceutical wastewater treatment by membrane distillation[ J ]. Desalination, 2020( 475 ): 114 - 148.
[ 18 ] 李再兴,左剑恶,剧盼盼,等. Fenton氧化法深度处理抗生素废水二级出水[ J ]. 环境工程学报,2013,7( 1 ):132 - 136.
[ 19 ] Jian Feng, Mengmeng Cao, Li Wang, et al. Ultra-thin DyFeO3/g-
C3N4 p-n heterojunctions for highly efficient photo-Fenton removal of oxytetracycline and antibacterial activity[ J ]. Journal of Alloys and Compounds, 2023( 939 ): 168 - 789.
[ 20 ] Lele Cui, Mingming Sun, Zhenghua Zhang. Flow-through integra-
tion of FeOCl/graphite felt-based heterogeneous electro-Fenton and Ti4O7-based anodic oxidation for efficient contaminant degradation[ J ]. Chemical Engineering Journal, 2022( 450 ): 138 - 263.
[ 21 ] Miaomiao Liu, Yu Zhang, Hong Zhang, et al. Ozonation as an effe-
ctive pretreatment for reducing antibiotic resistance selection potency in oxytetracycline production wastewater[ J ]. Desalination and Water Treatment, 2017( 74 ): 155 - 162.
[ 22 ] Lan Tang, Jiamei Huang, Chuanyan Zhuang, et al. Micronano-bu-
bble ozonation as an efficient pretreatment technology for raw oxytetracycline production wastewater discharged to biological treatment[ J ]. Chemical Engineering Journal, 2023( 476 ): 146 - 518.
[ 23 ] 王春平,刘清福,马子川. 催化臭氧氧化法降解土霉素废水[ J ]. 工业水处理,2005,( 4 ):56 - 58.
[ 24 ] Lei Wang, Jafar Ali, Zhibin Wang, et al. Oxygen nanobubbles en-
hanced photodegradation of oxytetracycline under visible light: Synergistic effect and mechanism[ J ]. Chemical Engineering Journal, 2020( 388 ): 124 - 227.
[ 25 ] 韩 爽,肖鹏飞. 过硫酸盐活化技术在四环素类抗生素降解中的应用进展[ J ]. 环境化学,2021,40( 9 ):2 873 - 2 883.
[ 26 ] Vladimir Stankov, Mirjana Novak Stankov, Matija Cvetni?, et al. Environmental aspects of UV-C-based processes for the treatment of oxytetracycline in water[ J ]. Environmental Pollution, 2021( 277 ): 116 - 797.
[ 27 ] Haonan Zhang, Qing Cao, Kaipeng Zhang, et al. Boron-doped bio-
char-nano loaded zero-valent iron to activate persulfate for the degradation of oxytetracycline[ J ]. Journal of Environmental Chemical Engineering, 2023, 11( 6 ): 111 - 502.
[ 28 ] 姜国平,赵俊娜,李贵霞,等. 土霉素废水处理技术研究进展[ J ]. 煤炭与化工,2014,37( 4 ):143 - 146.
[ 29 ] Yiqing Liu, Xuexiang He, Xiaodi Duan, et al. Photochemical degr-
adation of oxytetracycline: Influence of pH and role of carbonat-eradical[ J ]. Chemical Engineering Journal, 2015(276): 113 - 121.
[ 30 ] Huifang Zhang, Ying Wang, Chunyang Zhai. Construction of a novel p-n heterojunction CdS QDs/LaMnO3 composite for photodegradation of oxytetracycline[ J ]. Materials Science in Semiconductor Processing, 2022( 144 ): 106 - 568.
[ 31 ] 黄丽萍,陈东辉,黄满红,等. 铁碘共掺杂纳米TiO2光催化降解水中土霉素的研究[ J ]. 水处理技术, 2011, 37( 5 ):77 - 80.
[ 32 ] 胡继康,汪 恂,舒晓春,等. TiO2-Fe2O3复合光催化剂降解废水中土霉素研究[ J ]. 环境科学与技术, 2019, 42( 12 ):149 - 155.
[ 33 ] Runhua CHEN, Liyuan CHAI,Yunyan WANG, et al. Degrad-
ation of organic wastewater containing Cu-EDTA by Fe-C mi-
cro-electrolysis[ J ]. Transactions of Nonferrous Metals Society of China, 2012, 22( 4 ): 983 - 990.
[ 34 ] Feilong Zhang, Qinyan Yue, Yuan Gao, et al. Application for oxytetracycline wastewater pretreatment by Fe-C-Ni catalytic cathodic-anodic-electrolysis granular fillers from rare-earth tailings[ J ]. Ecotoxicology and Environmental Safety, 2018( 164 ): 641 - 647.
[ 35 ] 朱新锋,张乐观. 铁炭微电解-Fenton-生物接触氧化法处理土霉素废水[ J ]. 水处理技术, 2010, 36( 2 ):109 - 111.
[ 36 ] 李水秋. 铁碳微电解技术处理难降解废水的研究进展[ J ]. 广东化工, 2017, 44( 12 ):204 - 205, 194.
[ 37 ] Shannon M. Mitchell, Jeffrey L. Ullman, Amy L. Teel, et al. pH and temperature effects on the hydrolysis of three β-lactam antibiotics: Ampicillin, cefalotin and cefoxitin[ J ]. Science of the Total Environment, 2014( 466 ): 547 - 555.
[ 38 ] Qizhen Yi, Yu Zhang, Yingxin Gao, et al. Anaerobic treatment of antibiotic production wastewater pretreated with enhanced hydrolysis: Simultaneous reduction of COD and ARGs[ J ]. Water Research, 2017(110 ): 211 - 217.
[ 39 ] 宋旺旺,冀 东,武旭阳,等. 电子束辐照降解土霉素制药废水COD技术研究[ J ]. 工业水处理, 2021, 41( 2 ):80 - 83.
[ 40 ] 熊 强,冀 东,刘迎云,等. 响应面法优化电子束辐照降解土霉素制药废水中COD的研究[ J ]. 工业用水与废水, 2021, 52( 1 ):22 - 26. |
|
|
|
