Диссертация (1173071), страница 21
Текст из файла (страница 21)
Photochemical reactions involved in the totalmineralization of 2,4-D by iron(3+) / hydrogen peroxide / UV // 1993. Environ.Sci.133Technol. №27. P. 304-310.90. Nidheesh P.V., Gandhimathi R. Trends in electro-Fenton process for water andwastewater treatment: An overview // 2012. Desalination. №299.
P. 1-15.91. Sirés I., Brillas E., Oturan M.A., Rodrigo M.A., Panizza M., Electrochemicaladvanced oxidation processes: today and tomorrow. A review // 2014. Environ. Sci.Pollut. Res. №21 P. 8336-8367.92. Wang A., Qu J., Liu H., Ru J. Mineralization of an azo dye Acid Red 14 byphotoelectro-Fenton process using an activated carbon fiber cathode // 2008. Appl. Catal.B: Environ.
№84. P. 393-399.93. Flox C., Garrido J.A., Rodríguez R.M., Cabot P.-L., Centellas F., Arias C.,Brillas E. Mineralization of herbicide mecoprop by photoelectro-Fenton with UVA andsolar light // 2007. Catal. Today. №129. P.29-36.94. Garza-Campos B., Brillas E., Hernandez-Ramirez A., El-Ghenymy A.,Guzman-Mar J.L., Ruiz-Ruiz E.J. Salicylic acid degradation by advanced oxidationprocesses. Coupling of solar photoelectro-Fenton and solar heterogeneous photocatalysis// 2016.
Journal of hazardous materials. №319. P. 34-42.95. Dirany A., Sirés I., Oturan N., Oturan M. A. Electrochemical abatement of theantibiotic sulfamethoxazole from water // 2010. Chemosphere. №81. P. 594-602.96. Dirany A., Sirés I., Oturan N., Özcan A., Oturan M. A. ElectrochemicalTreatment of the Antibiotic Sulfachloropyridazine: Kinetics, Reaction Pathways, andToxicity Evolution // 2012. Environmental science and technology.
№46 (7). P. 40744082.97. Brinzila C.I., Pacheco M.J., Ciriaco L., Ciobanu R.C., Lopes A.Electrodegradation of tetracyclin on BDD anode // 2012. Chemical engineering journal.№209. P. 54-61.98. Yahiaoui I., Aissani-Benissad F., Fourcade F., Amrane A. Removal oftetracycline hydrochloride from water based on direct anodic oxidation (Pb/PbO2electrode) coupled to activated sludge culture // 2013. Chemical engineering journal.№221.
P. 418-425.99. Manilal V.B., Haridas A., Alexander R., Surender A.D. Photocatalytic134treatment of toxic organics in wastewater: toxicity of photodegradation products // 1992.Wat. Res. №26. P. 1035–1038.100. Bickley R.I., Slater M.J., Wang W-J. Engineering development of aphotocatalytic reactor for wastewater treatment // 2005. Process safety and environmentalprotection.
№83 (B3). P. 205-216.101. Duczmal L., Sobczynski A. Photocatalytic water purification: destruction ofresorcinol by irradiated titania // 2007. React. Kinet. Catal. Lett. Vol. 66. № 2. P. 289295.102. Matthews Ralph W. Photocatalytic oxidation of organic contaminants inwater: an aid to environmental preservation // 1992. Pure and application chemistry. №9. V. 64. P. 1285-1290.103.
Cui Y., Meng Q., Deng, X., Ma, Q., Zhang, H., Cheng, X., Li, X., Xie, M.,Cheng, Q. Fabrication of platinum nano-crystallites decorated TiO2 nano-tube arrayphotoelectrode and its enhanced photoelectrocatlytic performance for degradation ofaspirin and mechanism // 2016. J. Ind. Eng. Chem. №43. P. 177–184.104. Fujishima A., Hashimoto K., Watanabe T. TiO2 photocatalysis fundamentalsand applications // 1999.
A revolution in cleaning technology. P. 14-21.105. Linsebigler A.L., Lu G.Q., Yates Y.T. Photocatalysis on TiO2 surfaces:principles, mechanisms, and selected results // 1995. Chem. Rev. №95. P. 735- 758.106. Li. D., Jia. J., Zheng. T., Cheng. X., Yu. X. Construction and characterizationof visible light active Pdnano-crystallite decorated and C-N-S-co-doped TiO2 nanosheetarray photoelectrode for enhanced photocatalytic degradation of acetylsalicylic acid //2016. Catal. B Environ.
№188. P. 259–271.107. Cui Y., Meng Q., Deng X., Ma Q., Zhang H., Cheng X., Li X., Xie M., ChengQ. Fabrication of platinum nano-crystallites decorated TiO2 nano-tube arrayphotoelectrode and its enhanced photoelectrocatlytic performance for degradation ofaspirin and mechanism // 2016. J. Ind. Eng. Chem. №43. P. 177–184.108. Calza V.A., Sakkas C., Medana. C., Baiocchi A., Dimou E., Pelizzetti T.Albanis Photocatalytic degradation study of diclofenac over aqueous TiO2 suspensions //2006. Applied catalysis.
№67. P. 197-205.135109. Bruggeman P., Schram D., Gonzalez M.A., Rego R., Kong M.G., Leys C.Characterization of a direct dc-excited discharge in water by optical emissionspectroscopy // 2009. Plasma Sources Sci. Technol. №18. P. 199-205.110. Kanazawa S., Kawano, H.
Watanabe S., Furuki T., Akamine S., Ichiki R.,Ohkubo T., Kocik M., Mizeraczyk J. Observation of OH radicals produced by pulseddischarges on the surface of a liquid // 2011. Plasma Sources Sci. Technol. №20. 034010(8PP).111. Marotta E., Schiorlin M., Ren X., Rea M., Paradisi C. Advanced oxidationprocess for degradation of aqueous phenol in a dielectric barrier discharge reactor // 2011.Plasma Process. Polym. №8. P. 867-875.112.
Bruggeman P., Schram D.C. On OH production in water containingatmospheric pressure plasmas // 2010. Plasma Sources Sci. Technol. №19. 045025.113. Dobrin D., Bradu C., Magureanu M., Mandache N.B., Parvulescu V.I.,Degradation of diclofenac in water using a pulsed corona discharge // 2013.
Chem. Eng.J. №234. P. 389-396.114. Hoeben W.F.L.M., van Veldhuizen E.M., Rutgers W.R., Kroesen G.M.W.,Gas phase corona discharges for oxidation of phenol in an aqueous solution // 1999. J.Phys. D. Appl. Phys. №32. P. 133-137.115. Locke B.R., Shih K.-Y. Review of the methods to form hydrogen peroxidein electrical discharge plasma with liquid water // 2011. Plasma Sources Sci. Technol.№20. 034006.116. Brisset J.-L., Benstaali B., Moussa D., Fanmoe J., Njoyim-Tamungang E.Acidity control of plasma-chemical oxidation: applications to dye removal, urban wasteabatement and microbial inactivation // 2011. Plasma Sources Sci.
Technol. №20,034021.117. Brisset J.-L., Hnatiuc E. Peroxynitrite: a re-examination of the chemicalproperties of non-thermal discharges burning in air over aqueous solutions // 2012.Plasma Chem. Plasma Process. №32. P. 655-674.118. Lukes P., Dolezalova E., Sisrova I., Clupek M. Aqueous-phase chemistryand bactericidal effects from an air discharge plasma in contact with water: evidence for136the formation of peroxynitrite through a pseudo-second-order postdischarge reaction ofH2O2 and HNO2 // 2014.
Plasma Sources Sci. Technol. №23, 015019.119. Gerrity D., Stanford B.D., Trenholm R.A., Snyder S.A. An evaluation of apilot scale nonthermal plasma advanced oxidation process for trace organic compounddegradation // 2010.Water Res. №44. P. 493-504.120. Krause H., Schweiger B., Schuhmacher J., Scholl S., Steinfeld U.Degradation of the endocrine disrupting chemicals (EDCs) carbamazepine, clofibric acid,and iopromide by corona discharge over water // 2009. Chemosphere.
№75. P. 163-168.121. Magureanu M., Piroi D., Mandache N.B., David V., Medvedovici A.,Parvulescu V.I. Degradation of pharmaceutical compound pentoxifylline in water bynonthermal plasma treatment // 2010. Water Res. №44. P. 3445-3453.122. Krause H., Schweiger B., Prinz E., Kim J., Steinfeld U. Degradation ofpersistent pharmaceuticals in aqueous solutions by a positive dielectric barrier dischargetreatment // 2011.
J. Electrost. №69. P. 333-338.123. Liu Y., Sun Y., Hu J., He J., Mei S., Xue G., Ognier S. Removal of iopromidefrom an aqueous solution using dielectric barrier discharge // 2013. J. Chem. Technol.Biotechnol. №88. P. 468-473.124. Liu Y., Mei S., Iya-Sou D., Cavadias S., Ognier S. Carbamazepine removalfrom water by dielectric barrier discharge: comparison of ex situ and in situ discharge onwater // 2012. Chem. Eng. Process. №56.
P. 10-18.125. Magureanu M., Piroi D., Mandache N.B., David V., Medvedovici A., BraduC., Parvulescu V.I. Degradation of antibiotics in water by non-thermal plasma treatment// 2011. Water Res. №45. P. 3407-3416.126. Magureanu M., Dobrin D., Mandache N.B., Bradu C., Medvedovici A.,Parvulescu V.I. The mechanism of plasma destruction of enalapril and related metabolitesin water // 2013.
Plasma Process. Polym. №10. P. 459-468.127. Dobrin D., Magureanu M., Bradu C., Mandache N.B., Ionita P., ParvulescuV.I. Degradation of methylparaben in water by corona plasma coupled with ozonation //2014. Environ. Sci. Pollut. Res. №21. P. 12190-12197.128. Gur-Reznik S., Azerrad S.P., Levinson Y., Heller-Grossman L., Dosoretz137C.G. Iodinated contrast media oxidation by nonthermal plasma: the role of iodine as atracer // 2011.
Water Res. №45 (16). P. 5047-5057.129. Rong S.-P., Sun Y.-B. Wetted-wall corona discharge induced degradation ofsulfadiazine antibiotics in aqueous solution // 2013. J. Chem. Technol. Biotechnol. №89.P. 1351-1359.130. Zeng J., Yang B., Wang X., Li Z., Zhang X., Lei L. Degradation ofpharmaceutical contaminant ibuprofen in aqueous solution by cylindrical wetted-wallcorona discharge // 2015. Chem. Eng. J. №267. P.
282-288.131. Panorel I., Preis S., Kornev I., Hatakka H., Louhi-Kultanen M. Oxidation ofaqueous paracetamol by pulsed corona discharge // 2013a. Ozone Sci. Eng. №35. P. 116124.132. He D., Sun Y., Xin L., Feng J. Aqueous tetracycline degradation bynonthermal plasma combined with nano-TiO2 // 2014. Chem. Eng. J.
№258. P. 18-25.133. Rong S.-P., Sun Y.-B., Zhao Z.-H. Degradation of sulfadiazine antibioticsby water falling film dielectric barrier discharge // 2014. Chin. Chem. Lett. №25. P. 187192.134. Rosenfeldt J., Linden K.G., Canonica S., von Gunten U. Comparison of theefficiency of OH radical formation during ozonation and the advanced oxidationprocesses O3/H2O2 and UV/H2O2 // 2006. Water Res.
№40. P. 3695–3704.135. Mahamuni N.N., Adewuyi Y.G. Advanced oxidation processes (AOPs)involving ultrasound for wastewater treatment: a review with emphasis on cost estimation// 2010. Ultrason. Sonochem. №17. P. 990–1003.136. Zhao D., Sheng G., Chen C., Wang X. Enhanced photocatalytic degradationof methylene blue under visible irradiation on graphene–TiO2 dyade structure // 2012.Appl. Catal. B: Environ. №111–112.
![](https://s.studizba.com/z.php?f=/templates/si/i/noavatar.png&w=100&h=100&t=1"){kind=avatar}
