| 24 | 0 | 7 |
| 下载次数 | 被引频次 | 阅读次数 |
掺硼金刚石(BDD)是电化学领域中理想的电极材料之一。本文总结分析了电化学氧化机制,BDD电极的特性,BDD电极电化学氧化降解有机物的影响因素,以及BDD电极在电化学氧化降解有机废水的应用,并对BDD电极在废水处理中的应用进行了展望。
Abstract:Boron-doped diamond(BDD) is one of the ideal electrode materials in the field of electrochemistry. This paper reviews the electrochemical oxidation mechanisms, the characteristics of BDD electrodes, the factors influencing the electrochemical oxidation degradation of organic compounds by BDD electrodes, as well as the applications of BDD electrodes in the electrochemical oxidation degradation of organic wastewater. Additionally,prospects for the application of BDD electrodes in wastewater treatment are discussed.
[1]胡承志,刘会娟,曲久辉.电化学水处理技术研究进展[J].环境工程学报,2018,12(3):677-696.
[2]王博,张长安,赵利民,等.基于掺硼金刚石电极的工业废水处理研究进展[J].化工进展,2024,43(1):501-513.
[3] PANIZZA M,CERISOLA G. Direct and mediated anodic oxidation of organic pollutants[J]. Chemical reviews,2009,109(12):6541-6569.
[4] INIESTA J,MICHAUD P A,PANIZZA M,et al.Electrochemical oxidation of phenol at boron-doped diamond electrode[J]. Electrochimica Acta,2001,46(23):3573-3578.
[5] MIAO F,GAO M,YU X,et al. TiO2 electrocatalysis via three-electron oxygen reduction for highly efficient generation of hydroxyl radicals[J]. Electrochemistry Communications,2020,113:106687.
[6] XU J,LIU Y,LI D,et al. Insights into the electrooxidation of florfenicol by a highly active Ladoped Ti4O7 anode[J]. Separation and Purification Technology,2022,291:120904.
[7] MARTINEZ-HUITLE C A,BRILLAS E. Decontamination of wastewaters containing synthetic organic dyes by electrochemical methods:a general review[J].Applied Catalysis B:Environmental,2009,87(3-4):105-145.
[8] KAPALKA A,FOTI G,COMNINELLIS C. Kinetic modelling of the electrochemical mineralization of organic pollutants for wastewater treatment[J].Journal of Applied Electrochemistry,2008,38:7-16.
[9] COLEDAMD A C,AQUINO J M,SILVA B F,et al. Electrochemical mineralization of norfloxacin using distinct boron-doped diamond anodes in a filter-press reactor,with investigations of toxicity and oxidation by-products[J]. Electrochimica Acta,2016,213:856-864.
[10] SOUZA F,QUIJORNA S,LANZA M R,et al.Applicability of electrochemical oxidation using diamond anodes to the treatment of a sulfonylurea herbicide[J]. Catalysis Today,2017,280:192-198.
[11] GOMEZ-RUIZ B,GOMEZ-LAVIN S,DIBAN N,et al. Efficient electrochemical degradation of poly-and perfluoroalkyl substances(PFASs)from the effluents of an industrial wastewater treatment plant[J].Chemical Engineering Journal,2017,322:196-204.
[12] BRILLAS E,MARTINEZ-HUITLE C A. Decontamination of wastewaters containing synthetic organic dyes by electrochemical methods. An updated review[J].Applied Catalysis B:Environmental,2015,166:603-643.
[13] KOUADIO K E,KAMBIRE O,KOFFI K S,et al.Electrochemical oxidation of paracetamol on borondoped diamond electrode:analytical performance and paracetamol degradation[J]. Journal of Electrochemical Science and Engineering,2021,11(2):71-86.
[14] JUMAH R,ALSALMAN S,JUM'H I,et al. Chemical Structure Dependent Electrochemical Degradation of Antibiotics using Boron-Doped Diamond Electrodes[J]. Journal of Environmental Chemical Engineering,2024:114115.
[15] DOMINGUEZ J R,GONZALEZ T,CORREIA S.BDD electrochemical oxidation of neonicotinoid pesticides in natural surface waters. Operational,kinetic and energetic aspects[J]. Journal of Environmental Management,2021,298:113538.
[16] MOSTAFA E,BALTRUSCHAT H,GARCIASEGURA S. Unraveling the role of electrolytes during electrochemical oxidation by differential electrochemical mass spectrometry[J]. Electrochimica Acta,2021,387:138521.
[17] ZHANG C,DU X,ZHANG Z,et al. The peculiar roles of chloride electrolytes in BDD anode cells[J].RSC advances,2016,6(70):65638-65643.
[18] RABAAOUI N,SAADM E K,MOUSSAOUI Y,et al.Anodic oxidation of o-nitrophenol on BDD electrode:variable effects and mechanisms of degradation[J].Journal of hazardous materials,2013,250:447-453.
[19] HAMMAMI S,BELLAKHAL N,OTURAN N,et al. Degradation of Acid Orange 7 by electrochemically generated?OH radicals in acidic aqueous medium using a boron-doped diamond or platinum anode:A mechanistic study[J]. Chemosphere,2008,73(5):678-684.
[20] TISSOT G B,ANGLADA A,DIMITRIOUCHRISTIDIS P,et al. Kinetic experiments of electrochemical oxidation of iohexol on BDD electrodes for wastewater treatment[J]. Electrochemistry Communications,2012,23:48-51.
[21] LOOS G,SCHEERS T,VANEYCK K,et al. Electrochemical oxidation of key pharmaceuticals using a boron doped diamond electrode[J]. Separation and Purification Technology,2018,195:184-191.
[22]任梦娇,彭永丽,赵贺芳,等.电催化氧化降解高浓度农药废水的研究[J].水处理技术,2022,48(10):115-120.
[23] SOUZA F L,SAEZ C,LANZA M R V,et al. Removal of pesticide 2,4-D by conductive-diamond photoelectrochemical oxidation[J]. Applied Catalysis B:Environmental,2016,180:733-739.
[24] COLEDAMD A C,AQUINO J M,SILVA B F,et al.Electrochemical mineralization of norfloxacin using distinct boron-doped diamond anodes in a filter-press reactor,with investigations of toxicity and oxidation by-products[J]. Electrochimica Acta,2016,213:856-864.
[25] SOUZA F,QUIJORNA S,LANZAM R V,et al.Applicability of electrochemical oxidation using diamond anodes to the treatment of a sulfonylurea herbicide[J].Catalysis Today,2017,280:192-198.
[26]陈静双,朱泽基,尤家军,等. BDD电极电化学氧化技术处理印染工业退浆废水试验[J].西南科技大学学报,2024,39(1):60-65.
[27] CARNEIRO J F,AQUINO J M,SILVA B F,et al. Comparing the electrochemical degradation of the fluoroquinolone antibiotics norfloxacin and ciprofloxacin using distinct electrolytes and a BDD anode:evolution of main oxidation byproducts and toxicity[J]. Journal of Environmental Chemical Engineering,2020,8(6):104433.
[28] PANIZZA M,MARTINEZ-HUITLE C A. Role of electrode materials for the anodic oxidation of a real landfill leachate-comparison between Ti-Ru-Sn ternary oxide,PbO2 and boron-doped diamond anode[J].Chemosphere,2013,90(4):1455-1460.
[29] SHARMA S,BASU S,SHETTI N P,et al. Wasteto-energy nexus for circular economy and environmental protection:recent trends in hydrogen energy[J].Science of the Total Environment,2020,713:136633.
[30] AHMED M,MAVUKKANDY M O,GIWA A,et al.Recent developments in hazardous pollutants removal from wastewater and water reuse within a circular economy[J]. NPJ Clean Water,2022,5(1):1-25.
[31] DOSSANTOS E V,MARTINEZ-HUITLE C A,RODRIGO M A. The electro-refinery in organics:A new arising concept for valorization of wastes[J].Current Opinion in Electrochemistry,2023,39:101267.
[32]孙光溪,田哲,丁然,等.典型行业高浓度难降解工业废水深度处理技术研究进展[J].环境工程,2021,39(11):16-27,134.
[33] DUAN Y,TARAFDAR A,KUMAR V,et al.Sustainable biorefinery approaches towards circular economy for conversion of biowaste to value added materials and future perspectives[J]. Fuel,2022,325:124846.
[34] MEDEIROS M C,CASTROS S L,DOSSANTOS E V,et al. A proof of concept for the electro-refinery:Selective electroproduction of acetic acid from t-CNSL waste by using DSA electrode[J]. Electrochemistry Communications,2022,141:107356.
[35] MARTINEZ-HUITLE C A,RODRIGO M A,SIRES I,et al. A critical review on latest innovations and future challenges of electrochemical technology for the abatement of organics in water[J]. Applied Catalysis B:Environmental,2023,328:122430.
[36] SANTOS J E,DASILVA D,MARTINEZ-HUITLE C A,et al. Cathodic hydrogen production by simultaneous oxidation of methyl red and 2,4-dichlorophenoxyacetate aqueous solutions using Pb/PbO2,Ti/Sb-doped SnO2and Si/BDD anodes. Part 1:electrochemical oxidation[J]. RSC advances,2020,10(62):37695-37706.
[37] SANTOS J E,DA SILVA D R,MARTINEZHUITLE C A,et al. Cathodic hydrogen production by simultaneous oxidation of methyl red and 2,4-dichlorophenoxyacetate in aqueous solutions using PbO2,Sb-doped SnO2 and Si/BDD anodes. Part 2:hydrogen production[J]. RSC advances,2020,10(62):37947-37955.
[38] CAMARA CARDOZO J,DA SILVA D R,MARTINEZ-HUITLE C A,et al. Photovoltaic elect rochemically driven degradation of calcon dye with simultaneous green hydrogen production[J]. Materials,2022,15(21):7445.
[39] HENRIQUE J M M,MONTEIRO M K,CARDOZO J C,et al. Integrated-electrochemical approaches powered by photovoltaic energy for detecting and treating paracetamol in water[J]. Journal of Electroanalytical Chemistry,2020,876:114734.
[40] MEDEIROS M C,DOS SANTOS E V,MARTINEZHUITLE C A,et al. Obtaining high-added value products from the technical cashew-nut shell liquid using electrochemical oxidation with BDD anodes[J].Separation and Purification Technology,2020,250:117099.
[41] HARING A P,POLLOK D,STROCKER B R,et al. Beyond Kolbe and Hofer-Moest:electrochemical synthesis of carboxylic anhydrides from carboxylic acids[J]. ChemistryOpen,2022,11(5):e202200059
[42] OLIVEIRA H L,SANTOS J E,GONDIM A D,et al.Replacing oxygen evolution reaction in water splitting process by electrochemical energy-efficient production of high-added value chemicals with co-generation of green hydrogen[J]. Electrochimica Acta,2024,499:144692.
基本信息:
DOI:10.13744/j.cnki.cn21-1431/g4.2025.03.007
中图分类号:X703
引用信息:
[1]谢普凯提·买买提,李炟,刘士齐等.掺硼金刚石电极电化学氧化有机废水的研究进展[J].大连民族大学学报,2025,27(03):203-208.DOI:10.13744/j.cnki.cn21-1431/g4.2025.03.007.
基金信息:
大连市科技创新基金项目(2019J12SN70)