[Aktyacheva L, Emelyanova G. (1990). Activated carbon treatment with ozone. J Phys Chem 31: 21 [in Rus].]Search in Google Scholar
[Alexandrov YА, Tarunin BI, Perepletchikov МL. (1983). UV absorption of gaseous ozone. J Phys Chem LVII(10): 2385-2397 [in Rus].]Search in Google Scholar
[Atale S, Hitoshi M, Kaneko N, Taraichi K, Yano M. (1995). Ozone reactions with various carbon materials. Jap Pat CA, 123, 121871.]Search in Google Scholar
[Baldi M, Finochhio E, Pistarino C, Busca G. (1998). Evaluation of the mechanism of the oxy-dehydrogenation of propane over manganese oxide. J Appl Catal A: General 173: 61-74.]Search in Google Scholar
[Baltanas MA, Stiles AB, Katzer JR. (1986). Development of supported manganese oxides catalysts for partial oxidation: Preparation and hydrogenation properties. Appl Catal 28: 13-33.]Search in Google Scholar
[Becker KH, Schurath U, Seitz H. (1974). Ozone-olefi n reactions in the gas phase 1. Rate constants and activation energies. Int J Chem Kinet 6(5) 725-739.]Search in Google Scholar
[Bianchi CL, Pirola C, Ragaini V, Selli E. (2006). Mechanism and effi ciency of atrazine degradation under combined oxidation processes. Appl Catal B Environ 64(1-2): 131-138.]Search in Google Scholar
[Boreskov GK. (1965). The catalysis of isotopic exchange in molecular oxygen Adv Catal 15: 285-339.10.1016/S0360-0564(08)60556-8]Search in Google Scholar
[Brown TL, Le May HE Jr., Bursten BE, Burdge JR. (2002). Chemistry: The Central Science, Ninth edition, Prentice Hall, New Jersey.]Search in Google Scholar
[Buciuman F, Patcas F, Craciun R, Zhan DRT. (1998). Vibrational spectroscopy of bulk and supported manganese oxides. Phys Chem Chem Phys 1: 185-190.]Search in Google Scholar
[Chapman S. (1930a). On ozone and atomic oxygen in the upper atmosphere Phil Mag 10: 369-383.10.1080/14786443009461588]Search in Google Scholar
[Chapman S. (1930b). A theory of upper-atmospheric ozone. Mem Roy Meteorol Soc 3: 103-125]Search in Google Scholar
[Che M, Tench AJ. (1982). Characterization and reactivity of mononuclear oxygen species on oxide surfaces. Adv Catal 31: 77-133.]Search in Google Scholar
[Claudia C, Mincione E, Saladino R, Nicoletti R. (1994). Oxidation of substituted 2-thiouracils and pyrimidine-2-thione with ozone and 3,3-dimethyl-1,2-dioxirane. Tetrahedron 50(10): 3259-3272.]Search in Google Scholar
[Crutzen PJ, Schmailzl U. (1983). Chemical budgets of the stratosphere. Planet Space Sci 31: 1009-1032.]Search in Google Scholar
[DeMore WB, Raper O. (1964). Hartley and extinctiobn coeffi cients of ozone in the gas phase and in liquid nitrogen, carbon monoxide, and argon. J Phys Chem 68(2): 412-414.]Search in Google Scholar
[Deninno MP, McCarthy KE. (1997). The C-14 radiolabeled synthesis of the cholesterol absorption inhibitor cp-148,623 - A novel method for the incorporation of a C-14 label in enones. Tetrahedron 53(32): 11007-11020.]Search in Google Scholar
[Dhandapani B, Oyama ST. (1997). Gas phase ozone decomposition catalysts, J Appl Catal B: Environ 11(2): 129-166.10.1016/S0926-3373(96)00044-6]Search in Google Scholar
[Egorova GV, Popovich MP, Filipov YuV. (1988). Ozone destruction on the surface of ammonium hydrogen sulfate. J Phys Chem 29(4): 406-413 [in Russian].]Search in Google Scholar
[Einaga H, Futamura S. (2004). Comparative study on the catalytic activities of alumina-supported metal oxides for oxidation of benzene and cyclohexane with ozone. React Kinet Catal Lett 81(1): 121-128.]Search in Google Scholar
[Einaga H, Futamura S. (2005). Oxidation behavior of cyclohexane on alumina- supported manganese oxide with ozone. J Appl Catal B: Environ 60(1-2): 49-55.]Search in Google Scholar
[Einaga H, Harada M, Futamura S. (2005). Structural changes in alumina-supported manganese oxides during ozone decomposition. Chem Phys Lett 408(4-6): 377.]Search in Google Scholar
[Einaga H, Ogata A. (2009). Benzene oxidation with ozone over supported manganese oxide catalysts: Eff ect of catalyst support and reaction conditions. J Hazard Mater. 164(2-3): 1236-1241.]Search in Google Scholar
[Ellis WD, Tomets PV. (1972). Room-temperature catalytic decomposition of ozone. Atmospheric Environment 6(10): 707-714.]Search in Google Scholar
[Emelyanova G, Lebedev V, Kobozev N. (1964). Catalytic activity of noble metals in ozone destruction. J Phys Chem 38: 170-180 [in Russian].]Search in Google Scholar
[Emelyanova G, Lebedev V, Kobozev N. (1965). Ozone decomposition kinetics, J Phys Chem 39: 540-548 [in Russian].]Search in Google Scholar
[Emelyanova G, Strakhov B. (1968). Activity of NiO in ozone decomposition reaction, Adv Probl Phys Chem 2: 149-158 [in Russian].]Search in Google Scholar
[Farmen J, Gardiner B, Shanklin J. (1985). Large losses of total ozone in Antarctica reveal seasonal ClOx/NOx interaction. Nature 315: 207-210.]Search in Google Scholar
[Galimova LG, Komisarov VD, Denisov EТ. (1973). Ozonation of phenol. Rep Rus Acad Sci 2: 307-317 [in Russian].]Search in Google Scholar
[Gerchenson Yu, Zvenigorodskii S, Rozenstein V. (1990). Role of ozone for the greenhouse eff ect. Success Chemistry. 59: 1601-1609 [in Russian].]Search in Google Scholar
[Griggs M. (1968). Absorption coeffi cients of ozone in the ultraviolet and visible regions. J Chem Phys 49(2): 857-859.]Search in Google Scholar
[Hanisch F, Crowley JN. (2002). Ozone decomposition on Saharan dust: an experimental investigation. Atmos Chem Phys Discuss 2: 1809-1845.]Search in Google Scholar
[Hata K, Horiuchi M, Takasaki T. (1988). Preparation of high performance metal catalyst. Jap Pat CA, 108, 61754u.]Search in Google Scholar
[Hata K, Horiuchi M, Takasaki K, Ichihara S. (1987). Special technology for synthesis of catalysts, Jap Pat 62,201,648, Sep 5, to Nippon Shokubai Kagaku Kogyo Co., Ltd.]Search in Google Scholar
[Heisig C, Zhang W, Oyama ST. (1997). Decomposition of Ozone using Carbon Supported Metal Oxide Catalysts. J Appl Catal B: Environ 14(1-2): 117-129.]Search in Google Scholar
[Hon YS, Yan JL. (1993). The ozonolytic cleavage of cycloalkenes in the presence of methyl pyruvate to yield the terminally diff erentiated compounds. Tetrahedron Lett 34(41): 6591-6594.]Search in Google Scholar
[Houzellot JZ, Villermaux J. (1976). Etude dune einetique de decomposition hetergene ... sur oxyde de nicel. J de Chemie Physique 73(7-8): 807-812.]Search in Google Scholar
[Hunter P, Oyama ST. (2000). Control of Volatile Organic Compound Emissions: Conventional and Emerging Technologies, John Wiley & Sons, Inc.]Search in Google Scholar
[Imamura S, Ikebata M, Ito T, Ogita T. (1991). Decomposition of ozone on a silver catalyst. Ind Eng Chem Res 30(1): 217-221.]Search in Google Scholar
[Inn ECJ, Tanaka VJ. (1953). Absorption coeffi cient of ozone in the ultraviolet and visible regions. Opt Soc Amer 43(10): 870-872. Johnston HS. (1975). Global ozone balance in the natural stratosphere. Rev Geoph 13(5): 637-649.]Search in Google Scholar
[Kapteijn F, Singoredjo L, Andreini A, Moulijn JA. (1994). Activity and selectivity of pure manganese oxides in the selective catalytic reduction of nitric oxide with ammonia. J Appl Catal B: Environ 3(2-3): 173-189.]Search in Google Scholar
[Kashtanov L, Ivanova N, Rizhov B. (1936). Catalytic activity of metals in ozone decomposition. J. Applied Chemistry 9: 2176-2182 [in Russian].]Search in Google Scholar
[Kobayashi M, Mitsui K. (1988). Development for synthesis of zinc oxide, Jap. Pat. 63,267,439, Nov 4, to Nippon Shokubal Kagaku Kogyo Co., Ltd.]Search in Google Scholar
[Kobayashi M, Mitsui M, Kiichiro K. (1988). Chemical composition of metal oxide catalysts, Jap Pat, CA, 109, 175615a.]Search in Google Scholar
[Kobayashi M, Motonobu S, Mitsui M, Kiichiro K. (1989). Ozone decomposition on Pt/SiO2 catalyst, Jap Pat, CA, 110, 120511d.]Search in Google Scholar
[Kondratev K. (1989). Ozone reaction with OH radicals. Meteorology and Climate. 19: 212-218 [in Russian].]Search in Google Scholar
[Kondratev K. (1990). Ozonolysis of β-cyclodextrin. Success Chemistry 59: 1587-1598 [in Russian].]Search in Google Scholar
[Konova P, Stoyanova M, Naydenov A, Christoskova ST, Mehandjiev D. (2006). Catalytic oxidation of VOCs and CO by ozone over alumina supported cobalt oxide. J Appl Catal A: Gen 298: 109-114.]Search in Google Scholar
[Kutsuna S, Kasuda M, Ibusuki T. (1994).Transformation and decomposition of 1,1,1-trichloroethane on titanium dioxide in the dark and under photoillumination. Atmospheric Environment 28(9): 1627-1631.]Search in Google Scholar
[Kuwabara H, Fujita H. (1991). Highly specifi c surface ZrO2 for ozone destruction, Jap Pat 3016640, Jan 24, to Mitsubishi Heavy Industries, Ltd.]Search in Google Scholar
[Li W, Gibbs GV, Oyama ST. (1998). Mechanism of ozone decomposition on manganese oxide: 1. In situ laser Raman spectroscopy and ab initio molecular orbital calculations. J Am Chem Soc 120(35): 9041-9046.]Search in Google Scholar
[Li W, Oyama ST. (1996). Catalytic methane oxidation at low temperatures using ozone, in Heterogeneous Hydrocarbon Oxidation (Acs Symposium Series) (Warren BK and Oyama ST eds) pp. 364-373, ACS: Washington, DC.]Search in Google Scholar
[Li W, Oyama ST. (1998). The mechanism of ozone decomposition on manganese oxide: 2. Steady-state and transient kinetic studies. J Am Chem Soc 120(35): 9047-9052.]Search in Google Scholar
[Lin J, Kawai A, Nakajima T. (2002). Eff ective Catalysts for Decomposition of Aqueous Ozone. J Appl Catal B: Environ 39(2): 157-165.]Search in Google Scholar
[Lo Jacono M, Schiavello M. (1976). The infl uence of preparation methods on structural and catalytic properties of transition metal ions supported on alumina. Studies in Surface Science and Catalysis 1: 473-487.]Search in Google Scholar
[Lunin VV, Popovich MP, Tkachenko SN. (1998). Physical chemistry of ozone. Moscow State University Publisher, 480 p. [in Russian].]Search in Google Scholar
[Ma J, Chuah GK, Jaenicke S, Gopalakrishnan R, Tan KL. (1995). Catalysis by manganese oxide monolayers. Part 1: Alumina and magnesia supports. Berichte der Bunsengesellschaft für physikalische Chemie 99(2): 184-195.]Search in Google Scholar
[Ma J, Chuah GK, Jaenicke S, Gopalakrishnan R, Tan KL. (1995). Catalysis by manganese oxide monolayers. Part 2: Zirconia support. Berichte der Bunsengesellschaft für physikalische Chemie 100(5): 585-593.]Search in Google Scholar
[Ma J, Sui MH, Chen ZL, Li NW. (2004). Degradation of refractory organic pollutants by catalytic ozonation - activated carbon and Mn-loaded activated carbon as catalysts. Ozone Sci Eng 26(1): 3-10.]Search in Google Scholar
[Maltha A, Favre LFT, Kist HF, Zuur AP, Ponec V. (1994). Manganese oxides as catalysts for the selective reduction of nitrobenzene to nitrosobenzene. J Catal 149(2): 364-374.]Search in Google Scholar
[Martinov I, Demiduk V, Tkachenko S, Popovich M. (1994). Infl uence of the CuO and CoO on the process of ozone decomposition. J Phys Chem 68: 1972-1980 [in Rus].]Search in Google Scholar
[Martinov IV, Tkachenko SN, Demidyuk VI, Egorova GV, Lunin VV. (1999). NiO Addition Infl uence over Cement-containing Catalysts Activity in Ozone Decomposition. J Moscow Univ, Ser. 2: Chemistry 40: 355-361 [in Rus].]Search in Google Scholar
[Monchot W, Kampschulte W. (1907). Uber die Einwirkung von Ozon auf metallisches Silber und Quecksilber. Berichte der deutschen chemischen Gesellschaft 40(3): 2891.]Search in Google Scholar
[Mori, Katsushiko, Hasimoto, Akira. (1993). Partial carbon oxidation by ozone, Jap. Pat., CA, 118, 153488v.]Search in Google Scholar
[Muruganadham M, Chen SH, Wu JJ. (2007). Evaluation of water treatment sludge as a catalyst for aqueous ozone decomposition. Catal Commun 8(11): 1609-1614.]Search in Google Scholar
[Naydenov A, Konova P, Nikolov P, Klingstedt F, Kumar N, Kovacheva D, Stefanov P, Stoyanova R, Mehandjiev D. (2008). Decomposition of ozone on Ag/SiO2 catalyst for abatement of waste gases emissions. Catal Today 137(2-4): 471-474. Naydenov A, Mehandjiev D. (1993). Complete oxidation of benzene on manganese dioxide by ozone. J Appl Catal A: Gen 97(1): 17-22.]Search in Google Scholar
[Naydenov A, Stoyanova R, Mehandjiev D. (1995). Ozone decomposition and CO oxidation on CeO2. J Mol Catal A: Chem 98(1): 9-14.]Search in Google Scholar
[Olszyna K, Cadle RD, dePena RG. (1979). Stratospheric heterogeneous decomposition of ozone. J Geophys Res: Oceans 84(C4): 1771-1775.]Search in Google Scholar
[Oohachi K, Fukutake T, Sunao T. (1993). Method for synthesis of iron oxides, Jap Pat, CA, 119, 119194g.]Search in Google Scholar
[Oyama ST. (2000). Chemical and catalytic properties of ozone. Catal Rev Sci Eng 42(3): 279-322.]Search in Google Scholar
[Perry RH, Green D. (1997). Perry‘s chemical engineer‘s handbook, McGraw-Hill Professional, New York.]Search in Google Scholar
[Popovich M. (1988). Infl uence of the SiO in ozone decomposition reaction. J Phys Chem 29(5): 427-434 [in Russian].]Search in Google Scholar
[Popovich M. (1988). Investigation on ozone destruction over volcanic aerosols, J. Moscow Univ, Ser Chem 29: 29-35 [in Russian].]Search in Google Scholar
[Popovich MP, Smirnova NN, Sabitova LV. (1987). Infl uence of Na content on the volcanic aerosols activity in ozone decomposition. J Phys Chem 28(6): 548-557 [in Russian].]Search in Google Scholar
[Popovich M, Smirnova N, Sabitova L, Filipov Yu. (1985). Catalytic properties of copper oxide. J. Moscow Univ, Ser Chem 26: 167-177 [in Russian].]Search in Google Scholar
[Qi F, Chen Z, Xu B, Shen J, Ma J, Joll C, Heitz A. (2008). Infl uence of surface texture and acid-base properties on ozone decomposition catalyzed by aluminum (hydroxyl) oxides. Appl Catal B: Environ 84(3-4): 684-690.]Search in Google Scholar
[Radhakrishnan R, Oyama ST, Chen J, Asakura A. (2001). Electron Transfer Effects in Ozone Decomposition on Supported Manganese Oxide. J Phys Chem B 105(19): 4245-4253.]Search in Google Scholar
[Rakitskaya TL, Bandurko AY, Ennan AA, Paina VY, Rakitskiy AS. (2001). Carbonfi brous-material-supported base catalysts of ozone decomposition. Micropor Mesopor Mat 43(2): 153-160.]Search in Google Scholar
[Rakitskaya TL, Vasileva EK, Bandurko AY, Paina VY. (1994). Kinetics of Ozone Decomposition on Activated Carbons, Kinetics and Catalysis 35(1): 90-92.]Search in Google Scholar
[Rakovsky S, Nenchev L, Cherneva D. (1979). Decomposition of ozone in presence of NiO, in Proc. 4th Symp. Heterogeneous Catalysis, Varna, p. 231.]Search in Google Scholar
[Rakovsky SK, Zaikov GE. (2007). Kinetic and mechanism of ozone reactions with organic and polymeric compounds in liquid phase - 2nd edition, Nova Sci. Publ., Inc. New York.]Search in Google Scholar
[Razumovskii SD, Rakovsky SK, Shopov DM, Zaikov GE. (1983). Ozone and its reactions with organic compounds. Publ. House of Bulgarian Academy of Sciences, Sofi a, 287 p. [in Russian].]Search in Google Scholar
[Razumovskii SD, Zaikov GE. (1974). Ozone and its reactions with organic compounds, Moscow [in Russian].]Search in Google Scholar
[Rosal R, Rodriguez A, Gonzalo MS, Garcia-Calvo E. (2008). Catalytic ozonation of naproxen and carbamazepin on titanium dioxide. Appl Catal B: Environ 84(1-2): 48-57.]Search in Google Scholar
[Rubashov AM, Pogorelov VV, Strahov BV. (1972). Catalytic activity of Fe2O3 in decomposition of ozone. J Phys Chem 46(9): 2283-2291 [in Russian].]Search in Google Scholar
[Rubashov AM, Strahov BV. (1973). Formation of oxygen species on Fe2O3 surface during ozonation. J Phys Chem 47(8): 2115-2122 [in Russian].]Search in Google Scholar
[Schonbein CF. (1840). On the odour accompanying electricity and on the probability of its dependence on the presence of a new substance. Philosophical Magazine 17: 293-294.]Search in Google Scholar
[Schwab G, Hartman C. (1964). Metal catalysts for decomposition of ozone. J Phys Chem 6: 72-86 [in Russian].]Search in Google Scholar
[Skoumal M, Cabot PL, Centellas F, Arias C, Rodriguez RM, Garrido JA, Brillas E. (2006). Mineralization of paracetamol by ozonation catalyzed with Fe2+, Cu2+ and UVA light. Appl Catal B: Environ 66(3-4): 228-240.]Search in Google Scholar
[Solomon S, Garcia RR, Rowland F, Wueblles P. (1986). Regeneration rates of the stratospheric ozone. Nature 321: 755-758.]Search in Google Scholar
[Stoyanova M, Konova P, Nikolov P, Naydenov A, Christoskova ST, Mehandjiev D. (2006). Alumina-supported nickel oxide for ozone decomposition and catalytic ozonation of CO and VOCs. Chem Eng J 122(1-2): 41-46.]Search in Google Scholar
[Subrahmanyam C, Bulushev DA, Kiwi-Minsker L. (2005). Dynamic behaviour of activated carbon catalysts during ozone decomposition at room temperature. Appl Catal B: Environ 61(1-2): 98-106.]Search in Google Scholar
[Subrahmanyam C, Renken A, Kiwi-Minsker L. (2007). Novel catalytic nonthermal plasma reactor for the abatement of VOCs. Chem Eng J 134(1-3): 78-83.]Search in Google Scholar
[Sudak A, Volfson V. (1983). Catalytic Method of Removing Ozone Impurities from Air. The Role of Chemistry in Preserving the Environment. Scientifi c Notion, Kiev, 87-100 [in Russian].]Search in Google Scholar
[Sullivan RC, Thornberry T, Abbatt JPD. (2004). Ozone decomposition kinetics on alumina: Eff ects of ozone partial pressure, relative humidity and repeated oxidation cycles. Atmos Chem Phys 4: 1301-1310.]Search in Google Scholar
[Tanaka V, Inn ECJ, Watanabe KJ. (1953). Absorption coeffi cients of gases in the vacuum ultraviolet. Part IV. Ozone. J Chem Phys 21(10): 1651-1654.]Search in Google Scholar
[Tarunin BI, Perepletchikov ML, Klimova MN. (1981). Kinetics of decomposition of ozone in gradient-free reactor. Kinetics and Catalysis 22(2): 431-442 [in Russian].]Search in Google Scholar
[Taube H. (1957). Photochemical reactions of ozone in solution. Trans Faraday Soc 53: 656-665.]Search in Google Scholar
[Tchihara S. (1988). Co-catalyst for decomposition of ozone. Jap Pat, CA, 108, 192035h.]Search in Google Scholar
[Tench AJ, Lawson T. (1971). The formation of O− and O3 − adsorbed on an oxide surface. Chem Phys Lett 7(4): 459-460.]Search in Google Scholar
[Terui S, Miyoshi K, Yokota Y, Inoue A. (1990). Experimental method for ozone decomposition on silver oxide catalyst, Jap Pat 02,63,552, Mar 2.]Search in Google Scholar
[Terui S, Sadao K, Sano N, Nichikawa T. (1990). Synthesis of supported silver oxide catalysts, Jap Pat, CA, 112, 20404p.]Search in Google Scholar
[Terui S, Sadao K, Sano N, Nichikawa T. (1991). Investigation on Pd and Rh catalysts supported on colloidal polyurethane for ozone destruction, Jap Pat, CA, 114, 108179b.]Search in Google Scholar
[Thorp CE. (1955). Bibliography of Ozone Technology Volume 2: Physical and Pharmacological Properties, Armour Research.]Search in Google Scholar
[Tkalich VS, Klimovskii AO, Lissachenko AA. (1984). Study of heterogeneous reactions of ozone. Experimental installation and method. Kinetics and Catalysis 25(5): 1109-1116 [in Russian].]Search in Google Scholar
[Tong S, Liu W, Leng W, Zhang Q. (2003). Characteristics of MnO2 catalytic ozonation of sulfosalicylic acid propionic acid in water. Chemosphere 50(10): 1359-64.]Search in Google Scholar
[Valdes H, Sanches-Polo M, Rivera-Utrilla J, Zaror CA. (2002). Eff ect of ozone treatment on surface properties of activated carbon, Langmuir, 18, 2111.10.1021/la010920a]Search in Google Scholar
[Von Gunten U. (2003). Ozonation of drinking water: Part I. Oxidation kinetics and product formation, Water Res., 37, 1443-1463.]Search in Google Scholar
[Vupputuri R. (1988). Optical properties of stratospheric ozone, Atm. Environ., 22, 2809.]Search in Google Scholar
[Watson RT, Geller MA, Stolarski RS, Hampson RF, United States - Offi ce Of Space Science And Applications - Earth Science And Applications Division. (1986). Present state of knowledge of the upper atmosphere : an assessment report: processes that control ozone and other climatically important trace gases. NASA Reference Publication Nr. 1162, NASA, Scientifi c and Technical Information Branch; Springfi eld, VA.]Search in Google Scholar
[Wiley-VCH. (1991). Ullmann’s Encyclopedia of Industrial Chemistry. John Wiley and Sons, New York.]Search in Google Scholar
[Yamashita T, Vannice A. (1996). N2O Decomposition over Manganese Oxides, J Catalysis 161(1): 254-262.10.1006/jcat.1996.0183]Search in Google Scholar
[Yoshimoto M, Nakatsuji T, Nagano K, Yoshida K. (1990). Pd-catalyzed ozonation of aqueous phenol solution, Eur. Pat. 90,302,545.0, Sep 19, to Sakai Chemical Industry Co., Ltd.]Search in Google Scholar
[Zavadskii AV, Kireev SG, Muhin VM, Tkachenko SN, Chebkin VV, Klushin VN, Teplyakov DE. (2002). Eff ect of thermal treatment on the activity of hopcalite in ozone decomposition. J Phys Chem 76: 2072-2074 [in Russian].]Search in Google Scholar
[Zhao L, Ma J, Sun ZZ, (2008). Oxidation products and pathway of ceramic honeycomb-catalyzed ozonation for the degradation of nitrobenzene in aqueous solution. Appl Catal B: Environ 79(3): 244-253. ]Search in Google Scholar