Диссертация (1173071), страница 22
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P. 303–308.137. Madhavan J., Grieser F., Ashok kumar M. Kinetics of the sonophotocatalyticdegradation of orange G in presence of Fe[3+] // 2009. Anglais. №60. P. 2195-1202.138. Krejcikova S., Matejova L., Koci K., Obalova L., Matej Z., Capek L.,Solcova O. Preparation and characterization of Ag-doped crystalline titania forphotocatalysis applications // 2012.
Appl. Catal. B: Environ. №111–112. P. 119–125.138139. Liu L., He D., Zhao D. Study on photocatalysis degradation of phenol byusing Tourmaline/TiO2 system as catalyst // 2012. Adv. Mater. Res. №399–401. P. 1337–1341.140. Asilturk M., Sener S. TiO2-activated carbon photocatalysts: preparation,characterization and photocatalytic activities // 2012. Chem. Eng. J. №180.
P. 354–363.141. Balcioglu A., Otker M. Pre-treatment of antibiotic formulation wastewaterby O3, O3/H2O2, and O3/UV processes // 2004. Turk. J. Eng. Environ. Sci. №28. P. 325–331.142. Kim I., Yamashita N., Tanaka H. Performance of UV and UV/H2O2processes for the removal of pharmaceuticals detected in secondary effluent of a sewagetreatment plant in Japan // 2009. J. Hazard. Mater.
№166. P. 1134–1140.143. Kim I.H., Tanaka H., Iwasaki T., Takubo T., Morioka T., Kato Y.Classification of the degradability of 30 pharmaceuticals in water with ozone UV andH2O2 // 2008. Water Sci. Technol. №57. P. 195–200.144. Sanchez-Polo M., Rivera-Utrilla J., Mendez-Diaz J.D., Canonica S., vonGunten U. Photooxidation of naphthalene sulfonic acids: comparison between processesbased on O3, O3/activated carbon and UV/H2O2 // 2007. Chemosphere. №68. P. 1814–1820.145. Wu C., Linden K.G.
Degradation and byproduct formation of parathion inaqueous solutions by UV and UV/H2O2 treatment // 2008. Water Res. №42. P. 4780–4790.146. Rosenfeldt E. J., Linden K. G. Degradation of endocrine disruptingchemicals bisphenol A, ethinyl estradiol, and estradiol during UV photolysis andadvanced oxidation processes // 2004. Environmental science and technology. №38 (20).P. 5476-5483.147. Jesús García-Galan M., Anfruns A., Gonzalez-Olmos R., Rodriguez-MozazS., Comas J.
Advanced oxidation of the antibiotic sulfapyridine by UV/H2O2:Characterization of its transformation products and ecotoxicological implications // 2016.Chemosphere. №147. P. 451-459.148. Ф.В. Кармазинов Ультрафиолетовые технологии в современном мире:139Коллективная монография. Долгопрудный: Издательский Дом «Интеллект», 2012.392 с.149. S.
Parson Advanced oxidation processes for water treatment: Fundamentalsand Applications. Canada: IWA Publishing, 2004. 356 p.150. S.R. Sarathy, Mohseni M. An overview of UV-based advanced oxidationprocesses for drinking water treatment // 2006. IUVA News. №8 (2). P. 16.151. Wols B.A., Hofman-Caris C.H.M., Harmsen D.J.H., Beerendonk E.F.Degradation of 40 selected pharmaceuticals by UV/H2O2 // 2013.
Water Research. №47.P. 5876-5888152. Fernando L. Rosario-Ortiz, Eric C. Wert, Shane A. Snyder Evaluation ofUV/H2O2 treatment for the oxidation of pharmaceuticals in wastewater // 2010. WaterResearch. №44. P. 1440-1448.153. Hollender J., Zimmermann S.G., Koepke S., Krauss M., McArdell C.S., OrtC.S. Elimination of organic micropollutants in a municipal wastewater treatment plantupgraded with a full-scale post-ozonation followed by sand filtration // 2009. Environ.Sci. Technol. №43. P.
7862-7869.154. Gagnon C., Lajeunesse A., Cejka P., Gagne F., Hausler R. Degradationofselected acidic and neutral pharmaceutical products in a primary-treated wastewater bydisinfection processes // 2008. Ozone Sci.Eng. №3. P.387-392.155. Huber M.M., Canonica S., Park G.-Y., von Gunten U. Oxidation ofpharmaceuticals during ozonation and advanced oxidation processes // 2003.Environmental Science & Technology. №37.
P. 1016–1024.156. Zwiener С., Frimmel F.H. Oxidative treatment of pharmaceuticals in water// 2000. Water Research. №34. P. 1881-1885.157. Ferguson D.W., McGuire M.J., Koch B., Wolfe R.L., Aieta E.M. Comparingperoxone and ozone for controlling taste and odor compounds, disinfection byproducts,and microorganisms // 1990. J. Am. Water Works Assoc. №82. P. 181-191.158. Gómez-Pacheco C.V., Sánchez-Polo M., Rivera-Utrilla J., López-PenalverJ. Tetracycline removal from waters by integrated technologies based on ozonation andbiodegradation // 2011.
Chemical Engineering Journal. №178. P. 115-121.140159. Rosal R., Rodrıguez A., Perdigon-Melon J.A., Mezcua M., Hernando M.D.,Leton P., Garcıa-Calvo E., Aguera A., Fernandez-Alba A.R. Removal of pharmaceuticalsand kinetics of mineralization by O3/H2O2 in a biotreated municipal wastewater // 2008.Water Research. №42 (14). P.
3719-3728.160. Zwiener C., Frimmel F. H. Oxidative treatment of pharmaceuticals in water// 2000. Water Research. №6(34). P. 1881-1885.161. Емжина В.В., Иванцова Н.А., Кручинина Н.Е. Озонирование активныхфармацевтических субстанций в присутствии пероксида водорода // 2018. Вестниктехнологического университета. Т.21.
№4. C. 81-85.162. Parisheva Z., Nusheva L. Ozonation of aqueous solutions of salicylic acid //2007. Environment protection engineering. №1. V33 (1). P. 143-150.163. Kang J., Zhan W., Li D., Wang X., Song J., Liu D. Integrated catalytic wetair oxidation and biological treatment of wastewater from Vitamin B6 production // 2011.Physics and Chemistry of the Earth. Parts A/B/C. №36. P.455-458.164. Collado S., Laca A., Diaz M. Decision criteria for the selection of wetoxidationandconventionalbiologicaltreatment//2012.Journalof Environmental Management. №102. P.65-70.165.
Kolaczkowski S.T., Plucinski P., Beltran F.J., Rivas F.J., McLurgh D.B. Wetair oxidation: a review of process technologies and aspects in reactor design // 1999.The Chemical Engineering Journal. №73. P.143-160.166. Collado S., Laca A., Diaz M. Effect of the carboxylic substituent onthereactivity of the aromatic ring during the wet oxidation of phenolic acids // 2011.The Chemical Engineering Journal. №166.
P.940-946.167. Boock L.T. A quantitative analysis of reactions in supercritical water:experimental kinetics and mechanistic modeling // 1996. Ph.D. Dissertation. TheUniversity of Delaware.168. Li L., Chen P., Gloyna E. F. Generalized kinetic model for wet oxidation oforganic compounds // 1991. American Institute of Chemical Engineers Journal. №37(11). P.1687–1697.169. Bhargava S.K., Tardio J., Prasad J., Föger K., Akolekar D.B., Grocott S.C.141Wetoxidationandcatalyticwetoxidation//2006.IndustrialandEngineering Chemistry Research.
№45. P.1221-1258.170. Kim K.-H., Ihm S.-K Heterogeneous catalytic wet air oxidation of refractoryorganicpollutantsinindustrialwastewaters:Areview//2011.Journalof Hazardous Materials. №186. P.16-34.171. Collado S., Quero D., Laca A., Diaz M. Efficiency and sensitivity of the wetoxidation/biological steps in coupled pharmaceutical wastewater treatment // 2013.Chemical Engineering Journal. №234. P. 484-490.172. Галкин А.А., Лунин В. В.
Вода в суб- и сверхкритическом состояниях– универскальная среда для осуществления химических реакций // 2005. Успехи вхимии. №74 (1). С.24-40.173. Goto M., Nada T., Ogata A., Kodama A., Hirose T. Supercritical wateroxidation for the destruction of municipal excess sludge and alcohol distillery wastewaterof molasses // 1998.
The journal of supercritical fluids. №13. P. 277–282.174. Marrone P. A. Supercritical water oxidation-Current status of full-scalecommercial activity for waste destruction // 2013. The journal of supercritical fluids.№79. P. 283–288.175.
Benjume J.M., Sánchez-Oneto J., Portela J.R., Martínez de la Ossa E.J.Temperature control in a supercritical water oxidation reactor: Assessing strategies forhighly concentrated wastewaters // 2017. The journal of supercritical fluids. №119. P.72–80.176. Benjume J.M., Sánchez-Oneto J., Portela J.R., Jiménez-Espadafor F.J.,Martínez de la Ossa E.J. Simulation of supercritical water oxidation reactor in transitorystate: Application to time-dependent processes // 2016. The journal of supercritical fluids.№117.
P. 219–229.177. Kritzer P., Dinjus E. An assessment of supercritical water oxidation(SCWO): Existing problems, possible solutions and new reactor concepts // 2001. Chem.Eng. J. №83 (3). P. 207–214.178. Huddle T., Al-Atta A., Moran S., Lester E. Pseudo fluid modelling used inthe design of continuous flow supercritical water oxidation reactors with improved142corrosion resistance // 2017. J.
Supercrit. Fluids. №120 (2). P. 355–365.179. Vadillo V., Sánchez-Oneto J., Portela J.R., Martínez de la Ossa E.J.Problems in Supercritical Water Oxidation Process and Proposed Solutions // 2013. Ind.Eng. Chem. Res. №52. P. 7617-7629.180. Anitescu G., Tavlarides L. L. Methanol as a cosolvent and rate-enhancer forthe oxidation kinetics of 3,30,4,40-tetrachlorobiphenyl decomposition in supercriticalwater // 2002. J. Industrial & Engineering Chemistry Research, №41. P.
9–21.181. Anitescu G., Tavlarides L. L., Munteanu V. Decomposition ofmonochlorobiphenyl isomers in supercritical water in the presence of methanol // 2004.J. American Institute of Chemical Engineers Journal, №50. P. 1536–1544.182. Anitescu G., Tavlarides L. L. Oxidation of biphenyl in supercritical water:reaction kinetics, key pathways, and main products // 2005. J.
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