Диссертация (1173071), страница 20
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Фармацевтическаятехнология: Технология лекарственных форм: Учебник для студ. сред.проф. учеб.заведений. М.: Академия; Москва: 2004. 464 с.41. Moldovan Z., Chira R., Alder A.C. Environmental exposure of pharmaceuticalsand musk fragrances in the Somes River before and after upgrading the municipalwastewater treatment plant Cluj-Napoca, Romania // 2009.
Environ. Sci. Pollut. Res.№16. P. 46-54.42. A. Yu-Chen Lin, Tsung-Hsien Yu, Lateef S. K. Removal of pharmaceuticals insecondary wastewater treatment processes in Taiwan // 2009.Journal of HazardousMaterials. №167. P. 1163–1169.43. Benotti M. J., Trenholm R. A., Vanderford B. J., Holady J. C., Stanford B.
D.,Snyder S. A. Pharmaceuticals and endocrine disrupting compounds in U.S. DrinkingWater // 2009. Environmental Science and Technology. V.43. №3. P.597–603.44. Kümmerer K. Antibiotics in the aquatic environment – A review – Part I //2009. Chemosphere. №75. P. 417-434.45. Belkheiri D., Fourcade F., Geneste F., Floner D., Aït-Amar H., Amrane A.Feasibility of an electrochemical pre-treatment prior to a biological treatment fortetracycline removal // 2011. Separation and purification technology. №83(1). P. 151156.46. Камруков А.С., Козлов Н.П., Новиков Д.О. Новая технологическая схемаочистки сточных вод с высокой концентрацией органических загрязнителей // 2013.Безопасность в техносфере.
Т.2. №5 (44). С. 35-41.47. Стрикаленко Т. В. Некоторые проблемы токсикологии сточных вод. IVМеждународный конгресс по управлению отходами (Москва, 31 мая-3 июня, 2005):сборник докладов. М.: СИБИКО Инт., 2005. С. 647–648.48. Adams C., Wang Y., Loftin K., Meyer M.
Removal of antibiotics from surface129and distilled water in conventional water treatment processes // Journal of EnvironmentalEngineering. 2002. V.128. P.253–260.49. Ternes T.A., Meisenheimer M., Mcdowell D., Sacher F., Brauch H.–J., Haist–Gulde B., Preuss G., Wilme U., Zulei–Seibert N. Removal of pharmaceuticals duringdrinking water treatment // Environmental Science and Technology. 2002. V.36. №17.P.3855–3863.50.
Liu R., Wilding A., Whibberd A., Zhou J.L. Partition of endocrine–disruptingchemicals between colloids and dissolved phase as determined by cross–flowultrafiltration // 2005. Enviromental Science and Technology. V.39. P.2753–2761.51. Urase T., Kagawa C., Kikuta T. Factors affecting removal of pharmaceuticalsubstances and estrogens in membrane separation bioreactors // 2005. Desalination.№178. P.
107-113.52. Bellona C., Oelker G., Luna J., Filteau G., Amy G., Drewes J.E. Comparingnanofiltration and reverse osmosis for drinking water augmentation // 2008. JournalAmerican Water Works Association. V.100. №9. P.102–116.53. Zhou Q., Li Z., Shuang C., Li A., Zhang M., Wang M. Efficient removal oftetracycline by reusable magnetic microspheres with a high surface area // 2012.Chemical engineering journal.
№210. P. 350-356.54. Liu Q.-S., Zheng T., Wang P., Jiang J.-P., Li N. Adsorption isotherm, kineticand mechanism studies of some substituted phenols on activated carbon fibers // 2010.Chemical engineering journal. №157. P. 348-356.55. Rahardjo A. K., Susanto M. J. J., Kurniawan A., Indraswati N., Ismadji S. Modified Ponorogo bentonite for the removal of ampicillin from wastewater // 2011.Journal of hazardous materials.
№190. P. 1001-1008.56. Deegan A.M. Shaik B., Nolan K., Urell K. Treatment options for wastewatereffluents from pharmaceutical companies // 2011. International Journal of EnvironmentalScience and Technology. №8 (3) P. 649-666.57. Elucidation of the naproxen sodium adsorption onto activated carbon preparedfrom waste apricot: Kinetic, equilibrium and thermodynamic characterization58. Onal Y., Akmil-Basar C., Sarıcı-Ozdemir C. Adsorption isotherm, kinetic and130mechanism studies of some substituted phenols on activated carbon fibers // 2007.
Journalof hazardous materials. №148. P. 727-734.59. Jodeh S., Abdelwahab F., Jaradat N., Warad I., Jodeh W. Adsorption ofdiclofenac from aqueous solution using Cyclamen persicum tubers based activatedcarbon (CTAC) // 2016. Journal of the association of arab universities for basic andapplied sciences. №20. P. 32-38.60. Fogarty C. Photocatalytic oxidation of ciprofloxacin under UV-LED light:Bachelor of science degree. Worcester. 2013. P.46.61. Veriansyah B., Kim J.D.
Supercritical water oxidation for the destruction oftoxic organic wastewaters: A review // 2007. Journal of environmental science. №19. P.513-522.62. Moro T. R., Henrique F. R., Malucelli L. C., Ribas de Oliveira C. M, Filho M.A. C., Carvalho de Vasconcelos E. Adsorption of pharmaceuticals in water throughlignocellulosic fibers synergism // 2017. №171.
P. 57-65.63. 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. 484-490.64. Thomason T. B., Modell M. Supercritical water destruction of aqueous wastes.1984.
Journal of Hazardous Waste, №1(4). P. 453–467.65. Tijani J.O., Fatoba O.O., Madzivire G., Petrik L.F. A review of combinedAdvanced Oxidation Technologies for the removal of organic pollutants from water //2014. Water air soil pollut. №225 (2102). P. 1-30.66. Zazo J.A., Casas J.A., Mohedano A.F., Gilarranz M.A., Rodriguez J.J.Chemical pathway and kinetics of phenol oxidation by Fenton`s reagent //2005.Environmental Science and Technology. № 39. P. 9295–9320.67.
Strlic M., Radovic T., Kolar J., Pihlar B. Anti- and prooxidative properties ofgallic acid in Fenton-type systems // 2002. Food Chem. № 50. P. 6313–6317.68. Rodriguez J., Parra C., Contreras D., Freer J., Baesa J., Dihydroxybenzenes:drive Fenton reactions // 2001. Water Sci. Technol.
№44. P. 251–256.69. Zanta С. L. P. S., Friedrivh L. C., Machulek Jr. A., Higa K. M., Quina F.H.131Surfactant degradation by a catechol-driven Fenron reaction // 2010. Journal ofHazardous Materials. №178. P. 258-263.70. Chen F., Ma W.H., He J.J., Zhao J.C. Fenton degradation of malachite greencatalyzed by aromatic additives // 2002. J. Phys.
Chem. A. №106. P. 9485–9490.71. Strlic M., Radovic T., Kolar J., Pihlar B. Anti- and prooxidative properties ofgallic acid in Fenton-type systems // 2002. J. Agric. Food Chem. №50. P. 6313–6317.72. Catalkaya E.C., Kargi F. Effects of operating parameters on advancedoxidation of diuron by the Fenton`s reagent: a statistical design approach // 2007.Chemosphere.
№69. Р.485–492.73. Ben W., Qiang Z., Pan X., Chen M Removal of veterinary antibiotics fromsequencing batch reactor (SBR) pre-treated swine wastewater by Fenton`s reagent //2009. Water Research. №43. Р. 4392–4402.74. Elmolla E., Chaudhuri M. Optimization of Fenton process for treatment ofamoxicillin, ampicillin and cloxacillin antibiotics in aqueous solution // 2009.
The Journalof Hazardous Materials. №170. P. 666–672.75. Jyoti K.K., Pandit A.B. Water disinfection by acoustic and hydrodynamiccavitation // 2001. Biochemical engineering journal. №7 P. 201–212.76. Didenko Y.T., McNamara III W.B., Suslick K.S. Hot spot conditions duringcavitation in water // 1999.
The Journal of the American Chemical Society. №121 (24),P. 5817-5818.77. Lifka J., Ondruschka B., Hofmann J. The use of ultrasound for the degradationof pollutants in water: aqua sonolysise - a review // 2003. Engineering In Life Sciences.№3 (6), P. 253-262.78. Braeutigam P., Franke M., Schneider R.J., Lehmann A., Stolle A., OndruschkaB.
Degradation of carbamazepine in environmentally relevant concentrations in water byHydrodynamic-Acoustic-Cavitation (HAC) // 2012. Water Research. №46. P.2469-247779. Suresh Kumar M., Sonawane Aniruddha S.H., Pandit B. Degradation ofmethylene blue dye in aqueous solution using hydrodynamic cavitation based hybridadvanced oxidation processes // 2017. Chemical engineering and processing. №122. P.132288-295.80.
Barik A.J., Gogate P.R. Hybrid treatment strategies for 2,4,6-trichlorophenoldegradation based on combination of hydrodynamic cavitation and AOPs // 2018.Ultrasonics – Sonochemistry. №40. P. 383-394.81. Bagal M.V., Gogate P.R. Degradation of diclofenac sodium using combinedprocesses based on hydrodynamic cavitation and heterogeneous photocatalysis / // 2014.Ultrasonics – Sonochemistry. №21. P.1035–1043.82. Sirés I., Brillas E.
Remediation of water pollution caused by pharmaceuticalresidues based on electrochemical separation and degradation technologies: a review //2012. Environ. Int. №40. P. 212-229.83. Panizza M., Cerisola G. Direct and mediated anodic oxidation of organicpollutants // 2009. Chem.
Rev. №109. P. 6541-6569.84. Brillas E., Martínez-Huitle C.A. Decontamination of wastewaters containingsynthetic organic dyes by electrochemical methods: An updated review // 2015. Appl.Catal. B: Environ. №166-167. P. 603-643.85. Marselli B., García-Gomez J., Michaud P.A., Rodrigo M.A., Comninellis C.Electrogeneration of hydroxyl radicals on boron-doped diamond electrodes // 2003.
J.Electrochem. Soc. №150. P. D79-D83.86. El-Ghenymy A., Centellas F., Garrido J.A., Rodríguez R.M., Sirés I., CabotP.L., Brillas E. Decolorization and mineralization of Orange G azo dye solutions byanodic oxidation with a boron-doped diamond anode in divided and undivided tankreactors // 2014. Electrochim. Acta. №130. P. 568-576.87.
Boye B., Dieng M.M., Brillas E. Electrochemical degradation of 2,4,5trichlorophenoxyacetic acid in aqueous medium by peroxy-coagulation. Effect of pH andUV light // 2003. Electrochim. Acta. №48. P. 781-790.88. Garcia-Segura S., Brillas E. Advances in solar photoelectro-Fenton:Decolorization and mineralization of the Direct Yellow 4 diazo dye using an autonomoussolar pre-pilot plant // 2014. Electrochim. Acta. №140. P. 384-395.89. Sun Y., Pignatello J.J.
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