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Ozone: Science & Engineering
The Journal of the International Ozone Association
Volume 14, 1992 - Issue 4
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Original Articles

Ozone Decomposition on α-Fe2O3 Catalyst

D. Mehandjiev
&
A. Naidenov
Pages 277-282 | Received 15 Oct 1990, Accepted 26 Dec 1991, Published online: 23 Jul 2008

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Sung Su Kim, Sung Chang Hong & Keun Hee Han. (2013) Effect of Mn Dispersion on Gas Phase Ozone Decomposition at Room Temperature Using Natural Manganese Oxides. Ozone: Science & Engineering 35:6, pages 514-518.
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T. Murata, Y. Okita, M. Noguchi & I. Takase. (2004) Basic Parameters of Coplanar Discharge Ozone Generator. Ozone: Science & Engineering 26:5, pages 429-442.
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R. Gracia, S. Cortés, J. Sarasa, P. Ormad & J.L. Ovelleiro. (2000) Catalytic Ozonation with Supported Titanium Dioxide. The Stability of Catalyst in Water. Ozone: Science & Engineering 22:2, pages 185-193.
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W.T. Tsai, C.Y. Chang, F.H. Jung, C.Y. Chiu, W.H. Huang, Y.H. Yu, H.T. Liou, Y. Ku, J.N. Chen & C.F. Mao. (1998) Catalytic decomposition of ozone in the presence of water vapor. Journal of Environmental Science and Health, Part A 33:8, pages 1705-1717.
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C.Y. Chang, W.T. Tsai, L. Cheng, C.Y. Chiu, W.H. Huang, Y.H. Yu, H.T. Liou, Y. Ku & J.N. Chen. (1997) Catalytic decomposition of ozone in air. Journal of Environmental Science and Health . Part A: Environmental Science and Engineering and Toxicology 32:6, pages 1837-1847.
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Chen Dong, Jia-Jia Yang, Lin-Hua Xie, Ganglong Cui, Wei-Hai Fang & Jian-Rong Li. (2022) Catalytic ozone decomposition and adsorptive VOCs removal in bimetallic metal-organic frameworks. Nature Communications 13:1.
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Longgang Tao, Zhiqiang Zhang, Pengjing Chen, Guofeng Zhao, Ye Liu & Yong Lu. (2019) Thin-felt Al-fiber-structured Pd-Co-MnOx/Al2O3 catalyst with high moisture resistance for high-throughput O3 decomposition. Applied Surface Science 481, pages 802-810.
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Shuyan Gong, Zheng Xie, Weiman Li, Xiaofeng Wu, Ning Han & Yunfa Chen. (2019) Highly active and humidity resistive perovskite LaFeO3 based catalysts for efficient ozone decomposition. Applied Catalysis B: Environmental 241, pages 578-587.
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Xiaotong Li, Jinzhu Ma, Li Yang, Guangzhi He, Changbin Zhang, Runduo Zhang & Hong He. (2018) Oxygen Vacancies Induced by Transition Metal Doping in γ-MnO 2 for Highly Efficient Ozone Decomposition . Environmental Science & Technology 52:21, pages 12685-12696.
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P. Konova, A. Naydenov, Pl. Nikolov & N. Kumar. (2017) Low-temperature ozone decomposition, CO and iso-propanol combustion on silver supported MCM-41 and silica. Journal of Porous Materials 25:5, pages 1301-1308.
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Xianjie Wang, Manolis Romanias, Frédéric Thévenet & Antoine Rousseau. (2018) Geocatalytic Uptake of Ozone onto Natural Mineral Dust. Catalysts 8:7, pages 263.
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Shuyan Gong, Jiayuan Chen, Xiaofeng Wu, Ning Han & Yunfa Chen. (2018) In-situ synthesis of Cu2O/reduced graphene oxide composite as effective catalyst for ozone decomposition. Catalysis Communications 106, pages 25-29.
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Shuyan Gong, Xiaofeng Wu, Jilai Zhang, Ning Han & Yunfa Chen. (2018) Facile solution synthesis of Cu 2 O–CuO–Cu(OH) 2 hierarchical nanostructures for effective catalytic ozone decomposition . CrystEngComm 20:22, pages 3096-3104.
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Kun-Yi Andrew Lin, Tien-Yu Lin, Yu-Chien Chen & Yi-Feng Lin. (2017) Ferrocene as an efficient and recyclable heterogeneous catalyst for catalytic ozonation in water. Catalysis Communications 95, pages 40-45.
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Caixia Wang, Jinzhu Ma, Fudong Liu, Hong He & Runduo Zhang. (2015) The Effects of Mn 2+ Precursors on the Structure and Ozone Decomposition Activity of Cryptomelane-Type Manganese Oxide (OMS-2) Catalysts . The Journal of Physical Chemistry C 119:40, pages 23119-23126.
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Keshav Chand Soni, S. Chandra Shekar, Beer Singh & T. Gopi. (2015) Catalytic activity of Fe/ZrO2 nanoparticles for dimethyl sulfide oxidation. Journal of Colloid and Interface Science 446, pages 226-236.
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Zhihua Lian, Jinzhu Ma & Hong He. (2015) Decomposition of high-level ozone under high humidity over Mn–Fe catalyst: The influence of iron precursors. Catalysis Communications 59, pages 156-160.
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Changhui Zhao, Guozhi Zhang, Weihua Han, Jiecai Fu, Yongmin He, Zhenxing Zhang & Erqing Xie. (2013) Electrospun In2O3/α-Fe2O3 heterostructure nanotubes for highly sensitive gas sensor applications. CrystEngComm 15:33, pages 6491.
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Hongliang Han, Maojin Cui, Liling Wei, Haijun Yang & Jianquan Shen. (2011) Enhancement effect of hematite nanoparticles on fermentative hydrogen production. Bioresource Technology 102:17, pages 7903-7909.
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Hou Chuan Wang, Hsu Shang Liang & Moo Been Chang. (2011) Chlorobenzene oxidation using ozone over iron oxide and manganese oxide catalysts. Journal of Hazardous Materials 186:2-3, pages 1781-1787.
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S. Chandra Shekar, Keshav Soni, Rajendra Bunkar, Manoj Sharma, Beer Singh, Anil Nigam, Timir Mahato & R. Vijayaraghavan. (2009) Ozone assisted partial oxidation of DMS to DMSO on Fe based catalyst. Catalysis Communications 11:2, pages 77-81.
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L. A. Zaloznaya, S. N. Tkachenko, G. V. Egorova, I. S. Tkachenko, A. V. Sobolev, E. Z. Golosman, V. A. Troshina & V. V. Lunin. (2009) Ozone decomposition and benzene oxidation catalysts based on iron and manganese oxides as industrial wastes from water decontamination by ozone treatment. Catalysis in Industry 1:3, pages 224-228.
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Yongquan Yin, Yan Zheng, Shuzhong He & Quan Cui. (2009) Decomposion of Indoor Ozone on Activated Carbon-Supported Catalysts. Decomposion of Indoor Ozone on Activated Carbon-Supported Catalysts.
A. Naydenov, P. Konova, Pen. Nikolov, F. Klingstedt, N. Kumar, D. Kovacheva, P. Stefanov, R. Stoyanova & D. Mehandjiev. (2008) Decomposition of ozone on Ag/SiO2 catalyst for abatement of waste gases emissions. Catalysis Today 137:2-4, pages 471-474.
Crossref
M.M. Hassan & C.J. Hawkyard. 2007. Environmental Aspects of Textile Dyeing. Environmental Aspects of Textile Dyeing 149 190 .
Mohammad M Hassan, Christopher J Hawkyard & Peter A Barratt. (2006) Decolourisation of dyes and dyehouse effluent in a bubble-column reactor by ozonation in the presence of H2O2, KMnO4 or Ferral. Journal of Chemical Technology & Biotechnology 81:2, pages 158-166.
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Narendra Kumar, Petya M. Konova, Anton Naydenov, Teemu Heikill�, Tapio Salmi & Dmitry Yu. Murzin. (2004) Synthesis of Novel Ag Modified MCM-41 Mesoporous Molecular Sieve and Beta Zeolite Catalysts for Ozone Decomposition at Ambient Temperature. Catalysis Letters 98:1, pages 57-60.
Crossref
Mathias Ernst, Franck Lurot & Jean-Christophe Schrotter. (2004) Catalytic ozonation of refractory organic model compounds in aqueous solution by aluminum oxide. Applied Catalysis B: Environmental 47:1, pages 15-25.
Crossref
Fernando Beltr√°n. 2003. Ozone Reaction Kinetics for Water and Wastewater Systems. Ozone Reaction Kinetics for Water and Wastewater Systems.
Jianjun Lin, Akimasa Kawai & Tsuyoshi Nakajima. (2002) Effective catalysts for decomposition of aqueous ozone. Applied Catalysis B: Environmental 39:2, pages 157-165.
Crossref
Md.Mahbubul Hassan & Christopher J. Hawkyard. (2002) Ferral-catalyzed ozonation of aqueous dyes in a bubble-column reactor. Catalysis Communications 3:7, pages 281-286.
Crossref
Kevin C. BowerChristopher M. Miller. (2002) Filter Sand-Phosphate Buffer Effect on 2,4-Dinitrotoluene Ozonation. Journal of Environmental Engineering 128:2, pages 131-136.
Crossref
D Andreeva, T Tabakova, L Ilieva, A Naydenov, D Mehanjiev & M.V Abrashev. (2001) Nanosize gold catalysts promoted by vanadium oxide supported on titania and zirconia for complete benzene oxidation. Applied Catalysis A: General 209:1-2, pages 291-300.
Crossref
D. Mehandjiev, A. Naydenov & G. Ivanov. (2001) Ozone decomposition, benzene and CO oxidation over NiMnO3-ilmenite and NiMn2O4-spinel catalysts. Applied Catalysis A: General 206:1, pages 13-18.
Crossref
Antonello Filippi, Anna Troiani & Maurizio Speranza. (1997) XeO + and XeOH + Ions:  A New Class of Powerful Oxidative Oxygenating Agents in the Gas Phase . The Journal of Physical Chemistry A 101:49, pages 9344-9350.
Crossref
B. Dhandapani & S.T. Oyama. (1997) Gas phase ozone decomposition catalysts. Applied Catalysis B: Environmental 11:2, pages 129-166.
Crossref
Maurizio Speranza. (1996) Structure, Stability, and Reactivity of Cationic Hydrogen Trioxides and Thermochemistry of their Neutral Analogs. A Fourier-Transform Ion Cyclotron Resonance Study. Inorganic Chemistry 35:21, pages 6140-6151.
Crossref
Karl A. Newson, Stephanie M. Luc, Stephen D. Price & Nigel J. Mason. (1995) Electron-impact ionization of ozone. International Journal of Mass Spectrometry and Ion Processes 148:3, pages 203-213.
Crossref
A. Naydenov, R. Stoyanova & D. Mehandjiev. (1995) Ozone decomposition and CO oxidation on CeO2. Journal of Molecular Catalysis A: Chemical 98:1, pages 9-14.
Crossref
A. Naydenov & D. Mehandjiev. (1993) Complete oxidation of benzene on manganese dioxide by ozone. Applied Catalysis A: General 97:1, pages 17-22.
Crossref

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