参考文献

［1］ 中华人民共和国环境保护部.中国环境状况公报，2016.

［2］ Takht Ravanchi M， Kaghazchi T， Kargari A. Application of membrane separation processes in petrochemical industry： A review［J］. Desalination， 2009， 235（1）： 199-244.

［3］ Peng X， Yu Y， Tang C，et al. Occurrence of steroid estrogens， endocrine-disrupting phenols， and acid pharmaceutical residues in urban riverine water of the pearl river delta， south china［J］. The Science of the total environment， 2008， 397（1-3）： 158-166.

［4］ Shi W， Hu G， Chen S，et al. Occurrence of estrogenic activities in second-grade surface water and ground water in the yangtze river delta China［J］. Environmental Pollution， 2013， 181： 31-37.

［5］ Lee C-C， Jiang L-Y， Kuo Y-L， et al. The potential role of water quality parameters on occurrence of nonylphenol and bisphenol a and identification of their discharge sources in the river ecosystems［J］. Chemosphere， 2013， 91（7）： 904-911.

［6］ Xu X-R， Li H-B， Wang W-H，et al. Degradation of dyes in aqueous solutions by the fenton process［J］. Chemosphere， 2004， 57（7）： 595-600.

［7］ Weber E J， Adams R L. Chemical- and sediment-mediated reduction of the azo dye disperse blue 79［J］. Environmental Science & Technology， 1995， 29（5）： 1163-1170.

［8］ Gupta V K， Suhas. Application of low-cost adsorbents for dye removal-a review［J］. Journal of Environmental Management， 2009， 90（8）： 2313-2342.

［9］ Ali I， Asim M， Khan T A. Low cost adsorbents for the removal of organic pollutants from wastewater［J］. Journal of Environmental Management， 2012， 113： 170-183.

［10］ Ahmaruzzaman M. Industrial wastes as low-cost potential adsorbents for the treatment of wastewater laden with heavy metals［J］. Advances in Colloid and Interface Science， 2011， 166（1）： 36-59.

［11］ He Y， Li G， Wang H，et al. Effect of operating conditions on separation performance of reactive dye solution with membrane process［J］. Journal of Membrane Science， 2008， 321（2）： 183-189.

［12］ Murthy Z V P， Chaudhari L B. Separation of binary heavy metals from aqueous solutions by nanofiltration and characterization of the membrane using spiegler-kedem model［J］. Chemical Engineering Journal， 2009， 150（1）： 181-187.

［13］ Song G， Wang J， Chiu C-A，et al. Biogenic nanoscale colloids in wastewater effluents［J］. Environmental Science & Technology， 2010， 44（21）： 8216-8222.

［14］ Klavarioti M， Mantzavinos D， Kassinos D. Removal of residual pharmaceuticals from aqueous systems by advanced oxidation processes［J］. Environment International， 2009， 35（2）： 402-417.

［15］ Bethi B， Sonawane S H， Bhanvase B A，et al. Nanomaterials-based advanced oxidation processes for wastewater treatment： A review［J］. Chemical Engineering and Processing： Process Intensification， 2016， 109： 178-189.

［16］ Janus M， Tryba B， Inagaki M，et al. New preparation of a carbon-TiO₂ photocatalyst by carbonization of n-hexane deposited on TiO₂［J］. Applied Catalysis B： Environmental， 2004， 52（1）： 61-67.

［17］ Teh C M， Mohamed A R. Roles of titanium dioxide and ion-doped titanium dioxide on photocatalytic degradation of organic pollutants （phenolic compounds and dyes） in aqueous solutions： A review［J］. Journal of Alloys and Compounds， 2011， 509（5）： 1648-1660.

［18］ Zheng Z， Huang B， Qin X，et al. Strategic synthesis of hierarchical TiO₂ microspheres with enhanced photocatalytic activity［J］. Chemistry-A European Journal， 2010， 16（37）： 11266-11270.

［19］ Nakata K， Fujishima A. TiO₂ photocatalysis： Design and applications［J］. Journal of Photochemistry and Photobiology C： Photochemistry Reviews， 2012， 13（3）： 169-189.

［20］ Liu Z， Zhang X， Nishimoto S，et al. Highly ordered TiO₂ nanotube arrays with controllable length for photoelectrocatalytic degradation of phenol［J］. The Journal of Physical Chemistry C， 2008， 112（1）： 253-259.

［21］ McCullagh C， Robertson P K J， Adams M，et al. Development of a slurry continuous flow reactor for photocatalytic treatment of industrial waste water［J］.Journal of Photochemistry and Photobiology A： Chemistry， 2010， 211（1）： 42-46.

［22］ Zhang Z， Wu H， Yuan Y，et al. Development of a novel capillary array photocatalytic reactor and application for degradation of azo dye［J］. Chemical Engineering Journal， 2012， 184： 9-15.

［23］ Vella G， Imoberdorf G E， Sclafani A，et al. Modeling of a TiO₂-coated quartz wool packed bed photocatalytic reactor［J］. Applied Catalysis B： Environmental， 2010， 96（3）： 399-407.

［24］ Cassano A E， Alfano O M. Reaction engineering of suspended solid heterogeneous photocatalytic reactors［J］. Catalysis Today， 2000， 58（2）： 167-197.

［25］ Saien J， Delavari H， Solymani A R. Sono-assisted photocatalytic degradation of styrene-acrylic acid copolymer in aqueous media with nano titania particles and kinetic studies［J］. Journal of Hazardous Materials， 2010， 177（1）： 1031-1038.

［26］ Daghrir R， Drogui P， Robert D. Photoelectrocatalytic technologies for environmental applications［J］. Journal of Photochemistry and Photobiology A： Chemistry， 2012， 238： 41-52.

［27］ Meng X， Zhang Z， Li X. Synergetic photoelectrocatalytic reactors for environmental remediation： A review［J］. Journal of Photochemistry and Photobiology C： Photochemistry Reviews， 2015， 24： 83-101.

［28］ Garcia-Segura S， Brillas E. Applied photoelectrocatalysis on the degradation of organic pollutants in wastewaters［J］. Journal of Photochemistry and Photobiology C： Photochemistry Reviews， 2017， 31： 1-35.

［29］ Wang P， Lau I W， Fang H H. Electrochemical oxidation of leachate pretreated in an upflow anaerobic sludge blanket reactor［J］. Environmental technology， 2001， 22（4）： 373-381.

［30］ 李绍芬.反应工程［M］.北京：化学工业出版社，2006：323-334.

［31］ Gattrell M， Kirk D W. The electrochemical oxidation of aqueous phenol at a glassy carbon electrode［J］. The Canadian Journal of Chemical Engineering， 1990， 68（6）： 997-1003.

［32］ Vicent F， Moralló N E， Quijada C，et al. Characterization and stability of doped SnO₂ anodes［J］. Journal of Applied Electrochemistry， 1998， 28（6）： 607-612.

［33］ Correa-Lozano B， Comninellis C， Battisti A D. Service life of Ti/SnO₂-Sb₂O₅ anodes［J］. Journal of Applied Electrochemistry， 1997， 27（8）： 970-974.

［34］ Fernandes A， Morão A， Magrinho M，et al. Electrochemical degradation of c. I. Acid orange 7［J］. Dyes & Pigments， 2004， 61（3）： 287-296.

［35］ Pugazhenthiran N， Sathishkumar P， Murugesan S，et al. Effective degradation of acid orange 10 by catalytic ozonation in the presence of Au-Bi₂O₃ nanoparticles［J］. Chemical Engineering Journal， 2011， 168（3）： 1227-1233.

［36］ Peyton G R， Glaze W H. Destruction of pollutants in water with ozone in combination with ultraviolet radiation. 3. Photolysis of aqueous ozone［M］. F. Meiner， 1982.

［37］ Lü X-f， Ma H-r， Zhang Q，et al. Degradation of methyl orange by uv，O₃ and UV/O₃ systems： Analysis of the degradation effects and mineralization mechanism［J］. Research on Chemical Intermediates， 2013， 39（9）： 4189-4203.

［38］ Hsing H J， Chiang P C， Chang E E，et al. The decolorization and mineralization of acid orange 6 azo dye in aqueous solution by advanced oxidation processes： A comparative study［J］. Journal of Hazardous Materials， 2007， 141（1）： 8-16.

［39］ 沈钢， 应海燕， 张海明， 等. 水溶液中活性艳红ke-3b的臭氧超声联合脱除［J］. 环境工程学报， 2008， 2（12）： 1659-1662.

［40］ Song S， Ying H， He Z，et al. Mechanism of decolorization and degradation of ci direct red 23 by ozonation combined with sonolysis［J］. Chemosphere， 2007， 66（9）： 1782-1788.

［41］ He Z， Lin L， Song S，et al. Mineralization of c.I. Reactive blue 19 by ozonation combined with sonolysis： Performance optimization and degradation mechanism［J］. Separation & Purification Technology， 2008， 62（2）： 376-381.

［42］ Okawa K， Tsai T Y， Nakano Y，et al. Effect of metal ions on decomposition of chlorinated organic substances by ozonation in acetic acid［J］. Chemosphere， 2005， 58（4）： 523-527.

［43］ Moussavi G， Mahmoudi M. Degradation and biodegradability improvement of the reactive red 198 azo dye using catalytic ozonation with mgo nanocrystals［J］. Chemical Engineering Journal， 2009， 152（1）： 1-7.

［44］ Faria P C C， Órfão J J M， Pereira M F R. Activated carbon and ceria catalysts applied to the catalytic ozonation of dyes and textile effluents［J］. Applied Catalysis B Environmental， 2009， 88（3）： 341-350.

［45］ He H， Wu D， Lv Y，et al. Enhanced mineralization of aqueous reactive black 5 by catalytic ozonation in the presence of modified gac［J］. Desalination & Water Treatment， 2015， 57（32）： 1-10.

［46］ Liu Z-Q， Ma J， Cui Y-H，et al. Effect of ozonation pretreatment on the surface properties and catalytic activity of multi-walled carbon nanotube［J］. Applied Catalysis B：Environmental， 2009， 92（3）： 301-306.

［47］ Zhang S， Wang D， Quan X，et al. Multi-walled carbon nanotubes immobilized on zero-valent iron plates （fe0-cnts） for catalytic ozonation of methylene blue as model compound in a bubbling reactor［J］. Separation & Purification Technology， 2013， 116（37）： 351-359.

［48］ Huang G， Pan F， Fan G，et al. Application of heterogeneous catalytic ozonation as a tertiary treatment of effluent of biologically treated tannery wastewater［J］. J Environ Sci Health A Tox Hazard Subst Environ Eng， 2016， 51（8）： 626-633.

［49］ Kuši H， Boži A L， Koprivanac N. Fenton type processes for minimization of organic content in coloured wastewaters： Part i： Processes optimization［J］. Dyes & Pigments， 2007， 74（2）： 380-387.

［50］ Ramirez J H， Costa C A， Madeira L M. Experimental design to optimize the degradation of the synthetic dye orange ii using fenton’s reagent［J］. Catalysis Today， 2005， 107： 68-76.

［51］ Munoz M， Pedro Z M D， Casas J A，et al. Preparation of magnetite-based catalysts and their application in heterogeneous fenton oxidation-a review［J］. Applied Catalysis B Environmental， 2015， 176-177： 249-265.

［52］ Wang N， Zheng T， Zhang G，et al. A review on fenton-like processes for organic wastewater treatment［J］. Journal of Environmental Chemical Engineering， 2016， 4（1）： 762-787.

［53］ Babuponnusami A， Muthukumar K. Advanced oxidation of phenol： A comparison between fenton， electro-fenton， sono-electro-fenton and photo-electro-fenton processes［J］. Chemical Engineering Journal， 2012， 183（4）： 1-9.