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Iron oxide catalysts: Fenton and Fentonlike reactions – a review

Published online by Cambridge University Press:  09 July 2018

M. C. Pereira*
Affiliation:
Instituto de Ciência, Engenharia e Tecnologia, Universidade Federal dos Vales do Jequitinhonha e Mucuri, 39803- 371 Teófilo Otoni, Minas Gerais, Brazil
L. C. A. Oliveira
Affiliation:
Departamento de Química, ICEx, Universidade Federal de Minas Gerais, 31270-901 Belo Horizonte, Minas Gerais, Brazil
E. Murad
Affiliation:
Departamento de Química, ICEx, Universidade Federal de Minas Gerais, 31270-901 Belo Horizonte, Minas Gerais, Brazil
*

Abstract

Iron is the fourth most common element by mass in the Earth's crust and forms compounds in several oxidation states. Iron (hydr)oxides, some of which form inherently and exclusively in the nanometre-size range, are ubiquitous in nature and readily synthesized. These facts add up to render many Fe (hydr)oxides suitable as catalysts, and it is hardly surprising that numerous studies on the applications of Fe (hydr)oxides in catalysis have been published. Moreover, the abundant availability of a natural Fe source from rocks and soils at minimal cost makes the potential use of these as heterogeneous catalyst attractive.

Besides those Fe (hydr)oxides that are inherently nanocrystalline (ferrihydrite, Fe5HO8.4H2O, and feroxyhyte, δ’-FeOOH), magnetite (Fe3O4) is often used as a catalyst because it has a permanent magnetization and contains Fe in both the divalent and trivalent states. Hematite, goethite and lepidocrocite have also been used as catalysts in their pure forms, doped with other cations, and as composites with carbon, alumina and zeolites among others.

In this review we report on the use of synthetic and natural Fe (hydr)oxides as catalysts in environmental remediation procedures using an advanced oxidation process, more specifically the Fenton-like system, which is highly efficient in generating reactive species such as hydroxyl radicals, even at room temperature and under atmospheric pressure. The catalytic efficiency of Fe (hydr)oxides is strongly affected by factors such as the Fe oxidation state, surface area, isomorphic substitution of Fe by other cations, pH and temperature.

Type
Review
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2012

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References

Anaissi, F.J., Villalba, J.C., Fujiwara, S.T., Cótica, L.F., Lima de Souza, C.R. & Zamora-Peralta, P. (2009) Caracterizaçâo e propriedades do material coloidal nanoestruturado β-FeOOH/bentonita. Química Nova, 32, 2006–2010.Google Scholar
Andrade, A.L., Souza, D.M., Pereira, M.C., Fabris, J.D., & Domingues, R.Z., (2009) Catalytic effect of magnetic nanoparticles over the H2O2 decomposition reaction. Journal of Nanoscience and Nanotechnology, 9, 3695–3699.CrossRefGoogle ScholarPubMed
Andreozzi, R., D’Apuzzo, A. & Marotta, R. (2002) Oxidation of aromatic substrates in water/goethite slurry by means of hydrogen peroxide. Water Research, 36, 4691–4698.Google ScholarPubMed
Andreozzi, R., Canterino, M., Caprio, V., Di Somma, I. & Marotta, R. (2008) Use of an amorphous Fe oxide hydrated as catalyst for hydrogen peroxide oxidation of ferulic acid in water. Journal of Hazardous Materials, 152, 870–875.CrossRefGoogle Scholar
Baldrian, P., Merhautová, V., Gabriel, J., Nerud, F., Stopka, P., Hrubý, M. & Benes, M.J. (2006) Decolorization of synthetic dyes by hydrogen peroxide with heterogeneous catalysis by mixed iron oxides. Applied Catalysis B: Environmental, 66, 258–264.CrossRefGoogle Scholar
Barreiro, J.C. Capelato, M.D. Martin-Neto, L. & Hansen, H.C.B. (2007) Oxidative decomposition of atrazine by a Fenton-like reaction in a H2O2/ferrihydrite system. Water Research, 41, 55–62.Google Scholar
Basinska, A., Maniecki, T.P. & Jozwiak, W.K. (2006) Catalytic activity in water-gas shift reaction of platinum group metals supported on iron oxides. Reaction Kinetics and Catalysis Letters, 89, 319–324.CrossRefGoogle Scholar
Bogdanov, S.S., Aleksic, B.D., Mitov, I.G., Klisurski, D.G., & Petranovic, N.A. (1990) Comparative-study of the reduction kinetics of magnetites and derived ammonia- synthesis catalysts. Thermochimica Acta, 173, 71–79.CrossRefGoogle Scholar
Bossmann, S.H., Oliveros, E., Göb, S., Siegwart, S., Dahlen, E.P. Payawan, L. Jr., Straub, M., Wörner, M. & Braun, A.M. (1998) New evidence against hydroxyl radicals as reactive intermediates in the thermal and photochemically enhanced Fenton reactions. Journal of Physical Chemistry A, 102, 5542–5550.CrossRefGoogle Scholar
Botas, J.A., Melero, J.A., Martínez, F. & Pariente, M.I. (2010) Assessment of Fe2O3/SiO2 catalysts for the continuous treatment of phenol aqueous solutions in a fixed bed reactor. Catalysis Today, 149, 334–340.Google Scholar
Bray, W.C. & Gorin, M.H. (1932) Ferryl ion, a compound of tetravalent iron. Journal of the American Chemical Society, 54, 21242125.CrossRefGoogle Scholar
Castro, C.S., Guerreiro, M.C., Gonçalves, M., Oliveira, L.C.A. & Anastácio, A.S. (2009) Activated carbon/ iron oxide composites for the removal of atrazine from aqueous medium. Journal of Hazardous Materials, 164, 609–614.Google Scholar
Chou, S., Huang, C. & Huang, Y.-H. (2001) Heterogeneous and homogeneous catalytic oxidation by supported g-FeOOH in a fluidized-bed reactor: kinetic approach. Environmental Science and Technology, 35, 1247–1251.CrossRefGoogle Scholar
Cornell, R.M. & Schwertmann, U. (2003) The Iron Oxides – Structure, Properties, Reactions, Occurrences and Uses, 2nd ed., Wiley-VCH, Weinheim.CrossRefGoogle Scholar
Costa, R.C.C., Lelis, M.F.F., Oliveira, L.C.A., Fabris, J.D. Ardisson, J.D., Rios, R.R.V.A., Silva, C.N. & Lago, R.M. (2006) Novel active heterogeneous Fenton system based on Fe3–xMxO4 (Fe, Co, Mn, Ni): the role of M2+ species on the reactivity towards H2O2 reactions. Journal of Hazardous Materials, 129, 171–178.CrossRefGoogle ScholarPubMed
Costa, R.C.C., Moura, F.C.C., Ardisson, J.D. Fabris, J.D. & Lago, R.M. (2008) Highly active heterogeneous Fenton-like systems based on Fe0/Fe3O4 composites prepared by controlled reduction of iron oxides. Applied Catalysis B: Environmental, 83, 131–139.Google Scholar
Dantas, T.L.P., Mendonça, V.P., José, H.J., Rodrigues, A.E. & Moreira, R.F.P.M. (2006) Treatment of textile wastewater by heterogeneous Fenton process using a new composite Fe2O3/carbon. Chemical Engineering Journal, 118, 77–82.Google Scholar
Datta, P., Rihko-Struckmann, L. K. & Sundmacher, K. (2011) Influence of molybdenum on the stability of iron oxide materials for hydrogen production with cyclic water gas shift process. Materials Chemistry and Physics, 129, 1089–1095.CrossRefGoogle Scholar
de Souza, W.F., Guimarães, I.R., Oliveira, L.C.A., Guerreiro, M.C., Guarieiro, A.L.N. & Carvalho, K.T.G. (2007) Natural and H2-reduced limonite for organic oxidation by a Fenton-like system: mechanism study via ESI-MS and theoretical calculations. Journal of Molecular Catalysis A: Chemical, 278, 145–151.Google Scholar
de Souza, W.F., Guimarães, I.R., Oliveira, L.C.A, Giroto, A.S., Guerreiro, M.C. & Silva, C.L.T. (2010) Effect of Ni incorporation into goethite in the catalytic activity for the oxidation of nitrogen compounds in petroleum. Applied Catalysis A: General, 381, 36–41.Google Scholar
Dong, H.H., Xie, M.J., Xu, J., Li, M.F., Peng, L.M., Guo X, F. & Ding, W.P. (2011) Iron oxide and alumina nanocomposites applied to Fischer-Tropsch synthesis. Chemical Communications, 47, 4019–4021.CrossRefGoogle ScholarPubMed
Du, W., Xu, Y. & Wang, Y. (2008) Photoinduced degradation of Orange II on different iron (hydr)oxides in aqueous suspension: rate enhancement on addition of hydrogen peroxide, silver nitrate, and sodium fluoride. Langmuir, 24, 175–181.Google Scholar
Ensing, B., Buda, F. & Baerends, E.J. (2003) Fenton-like chemistry in water: oxidation catalysis by Fe(III) and H2O2 . Journal of Physical Chemistry A, 107, 5722–5731.CrossRefGoogle Scholar
Fenton, H.J.H. (1894) Oxidation of tartaric acid in presence of iron. Journal of the Chemical Society, Transactions, 65, 899–910.CrossRefGoogle Scholar
Ferraz, W., Oliveira, L.C.A., Dallago, R. & Conceição, L. (2007) Effect of organic acid to enhance the oxidative power of the Fenton-like system: computational and empirical evidences. Catalysis Communications, 8, 131–134.Google Scholar
Gong, F.Y., Ye, T.Q., Yuan, L.X., Kan, T., Torimoto, Y., Yamamoto, M. & Li, Q.X. (2009) Direct reduction of iron oxides based on steam reforming of bio-oil: a highly efficient approach for production of DRI from bio-oil and iron ores. Green Chemistry, 11, 2001–2012.CrossRefGoogle Scholar
Gonzalez-Olmos, R., Holzer, F., Kopinke, F.D. & Georgi, A. (2011) Indications of the reactive species in a heterogeneous Fenton-like reaction using Fe-containing zeolites. Applied Catalysis A: General, 398, 44–53.Google Scholar
Gordon, T.R. & Marsh, A.L. (2009) Temperature dependence of the oxidation of 2– chlorophenol by hydrogen peroxide in the presence of goethite. Catalysis Letters, 132, 349–354.CrossRefGoogle Scholar
Gregor, C., Hermanek, M., Jancik, D., Pechousek, J., Filip, J., Hrbac, J. & Zboril, R. (2010) The effect of surface area and crystal structure on the catalytic efficiency of iron(III) oxide nanoparticles in hydrogen peroxide decomposition. European Journal of Inorganic Chemistry, 2010, 2343–2351.Google Scholar
Guimarães, I.R., Oliveira, L.C.A., Queiroz, P.F., Ramalho, T.C., Pereira, M., Fabris, J.D. & Ardisson, J.D. (2008) Modified goethites as catalyst for oxidation of quinoline: Evidence of heterogeneous Fenton process. Applied Catalysis A: General, 347, 89–93.CrossRefGoogle Scholar
Guimarães, I.R., Giroto, A., Oliveira, L.C.A., Guerreiro, M.C., Lima, D.Q. & Fabris, J.D. (2009) Synthesis and thermal treatment of Cu-doped goethite: Oxidation of quinoline through heterogeneous Fenton process. Applied Catalysis B: Environmental, 91, 581–586.CrossRefGoogle Scholar
Guo, L., Chen, F., Fan, X., Cai, W. & Zhang, J. (2010) Sdoped a-Fe2O3 as a highly active heterogeneous Fenton-like catalyst towards the degradation of acid orange 7 and phenol. Applied Catalysis B: Environmental, 96, 162–168.CrossRefGoogle Scholar
Haber, F. & Weiss, J. (1934) The catalytic decomposition of hydrogen peroxide by iron salts. Proceedings of the Royal Society of London A, 147, 332–351.Google Scholar
Han, S.K. Hwang, T.M. Yoon, Y. & Kang, J.W. (2011) Evidence of singlet oxygen and hydroxyl radical formation in aqueous goethite suspension using spintrapping electron paramagnetic resonance (EPR). Chemosphere, 84, 1095–1101.Google Scholar
He, J., Tao, X., Ma, W.H. & Zhao, J.C. (2002) Heterogeneous photo-Fenton degradation of an azo dye in aqueous H2O2/iron oxide dispersions at neutral pHs. Chemistry Letters, 31, 86–87.Google Scholar
Hermanek, M., Zboril, R., Medrik, I., Pechousek, J. & Gregor, C. (2007) Catalytic efficiency of iron(III) oxides in decomposition of hydrogen peroxide: competition between the surface area and crystallinity of nanoparticles. Journal of the American Chemical Society, 129, 10929–10936.CrossRefGoogle ScholarPubMed
Holme, B. (1997) Morphology and crystallographic relationships in reduced magnetite: a comprehensive structural study of the porous iron ammonia synthesis catalyst. Journal of Catalysis, 167, 12–24.CrossRefGoogle Scholar
Hu, X., Liu, B., Deng, Y., Chen, H., Luo, S., Sun, C., Yang, P. & Yang, S. (2011) Adsorption and heterogeneous Fenton degradation of 17a-methyltestosterone on nano Fe3O4/MWCNTs in aqueous solution. Applied Catalysis B: Environmental, 107, 274–283.CrossRefGoogle Scholar
Huang, C.P. & Huang, Y.H. (2008) Comparison of catalytic decomposition of hydrogen peroxide and catalytic degradation of phenol by immobilized iron oxides. Applied Catalysis A: General, 346, 140–148.CrossRefGoogle Scholar
Huang, H.H., Lu, M.C. & Chen, J.N. (2001) Catalytic decomposition of hydrogen peroxide and 2-chlorophenol with iron oxides. Water Research, 35, 2291–2299.CrossRefGoogle ScholarPubMed
Jung, Y.S., Lim, W.T., Park, J.Y. & Kim, Y.H. (2009) Effect of pH on Fenton and Fenton-like oxidation. Environmental Technology, 30, 183–190.CrossRefGoogle ScholarPubMed
Kang, S.H., Bae, J.W., Cheon, J.Y., Lee, Y.J., Ha, K.S., Jun, K.W., Lee, D.H. & Kim, B.W. (2011) Catalytic performance on iron-based Fischer-Tropsch catalyst in fixed-bed and bubbling fluidized-bed reactor. Applied Catalysis B:Environmental, 103, 169–180.CrossRefGoogle Scholar
Kong, S.-H., Watts, R.J. & Choi, J.-H. (1998) Treatment of petroleum-contaminated soils using iron mineral catalyzed hydrogen peroxide. Chemosphere, 37, 1473–1482.Google Scholar
Kremer, M.L. (1999) Mechanism of the Fenton reaction. Evidence for a new intermediate. Physical Chemistry: Chemical Physics, 1, 3595–3605.Google Scholar
Kremer, M.L. (2003) The Fenton reaction. Dependence of the rate on pH. Journal of Physical Chemistry A, 107, 1734–1741.Google Scholar
Kwan, W. & Voelker, B.M. (2002) Decomposition of hydrogen peroxide and organic compounds in the presence of dissolved iron and ferrihydrite. Environmental Science and Technology, 36, 1467–1476.Google Scholar
Lee, S., Oh, J. & Park, Y. (2006) Degradation of phenol with Fenton-like treatment by using heterogeneous catalyst (modified iron oxide) and hydrogen peroxide. Bulletin of the Korean Chemical Society, 27, 489–494.Google Scholar
Li, Z. & Shanks, B.H. (2011) Role of Cr and V on the stability of potassium-promoted iron oxides used as catalysts in ethylbenzene dehydrogenation. Applied Catalysis A: General, 405, 101–107.Google Scholar
Liang, X., Zhong, Y., Zhu, S., Zhu, J., Yuan, P., He, H. & Zhang, J. (2010a) The decolorization of Acid Orange II in non-homogeneous Fenton reaction catalyzed by natural vanadium– titanium magnetite. Journal of Hazardous Materials, 181, 112–120.Google Scholar
Liang, X., Zhu, S., Zhong, Y., Zhu, J., Yuan P, He, H. & Zhang, J. (2010b) The remarkable effect of vanadium doping on the adsorption and catalytic activity of magnetite in the decolorization of methylene blue. Applied Catalysis B: Environmental, 97, 151–159.Google Scholar
Liao, Q., Sun, J. & Gao, L. (2009) Degradation of phenol by heterogeneous Fenton reaction using multi-walled carbon nanotube supported Fe2O3 catalysts. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 345, 95–100.Google Scholar
Lim, H., Lee, J., Jin, S., Kim, J., Yoon, J. & Hyeon, T. (2006) Highly active heterogeneous Fenton catalyst using iron oxide nanoparticles immobilized in alumina coated mesoporous silica. Chemical Communications, 463–465.Google ScholarPubMed
Lin, Y.J., Zhou, S., Sheehan, S.W. & Wang, D.W. (2011) Nanonet-based hematite heteronanostructures for efficient solar water splitting. Journal of the American Chemical Society, 133, 2398–2401.CrossRefGoogle ScholarPubMed
Liou, M.J. & Lu, M.C. (2008) Catalytic degradation of explosives with goethite and hydrogen peroxide. Journal of Hazardous Materials, 151, 540–546.CrossRefGoogle ScholarPubMed
Liu, Y. & Sun, D. (2007) Effect of CeO2 doping on catalytic activity of Fe2O3/γ-Al2O3 catalyst for catalytic wet peroxide oxidation of azo dyes. Journal of Hazardous Materials, 143, 448–454.Google Scholar
Lu, M.C. (2000) Oxidation of chlorophenols with hydrogen peroxide in the presence of goethite. Chemosphere, 40, 125–130.CrossRefGoogle ScholarPubMed
Lu, M.C. Chen, J.N. & Huang, H.H. (2002) Role of goethite dissolution in the oxidation of 2-chlorophenol with hydrogen peroxide. Chemosphere, 46, 131–136.Google Scholar
Luo, M., Bowden, D. & Brimblecombe, P. (2009) Catalytic property of Fe-Al pillared clay for Fenton oxidation of phenol by H2O2 . Applied Catalysis B: Environmental, 85, 201–206.CrossRefGoogle Scholar
Magalhães, F., Pereira, M.C. Botrel, S.E.C., Fabris, J.D., Macedo, W.A., Mendonça, R., Lago, R.M. & Oliveira, L.C.A. (2007) Cr-containing magnetites Fe3-xCrxO4: the role of Cr3+ and Fe2+ on the stability and reactivity towards H2O2 reactions. Applied Catalysis A: General, 332, 115–123.CrossRefGoogle Scholar
Matsuoka, K., Shimbori, T., Kuramoto, K., Hatano, H. & Suzuki, Y. (2006) Steam reforming of woody biomass in a fluidized bed of iron oxide-impregnated porous alumina. Energy & Fuels, 20, 27272731.Google Scholar
Matta, R., Hanna, K. & Chiron, S. (2007) Fenton-like oxidation of 2,4,6-trinitrotoluene using different iron minerals. Science of the Total Environment, 385, 242–251.Google Scholar
Matta, R., Hanna, K., Kone, T. & Chiron, S. (2008) Oxidation of 2,4,6-trinitrotoluene in the presence of different iron-bearing minerals at neutral pH. Chemical Engineering Journal, 144, 453–458.Google Scholar
Melero, J.A., Calleja, G., Martínez, F. & Molina, R. (2006) Nanocomposite of crystalline Fe2O3 and CuO particles and mesostructured SBA-15 silica as an active catalyst for wet peroxide oxidation processes. Catalysis Communications, 7, 478–483.CrossRefGoogle Scholar
Menini, L., Parreira, L.A., Pereira, M.C., Fabris, J.D. & Gusevskaya, E.V. (2008) Cobalt- and manganesesubstituted ferrites as efficient single site heterogeneous catalysts for aerobic oxidation of monoterpenic alkenes under solvent free conditions. Journal of Catalysis, 254, 355–364.CrossRefGoogle Scholar
Menini, L., Pereira, M.C., Ferreira, A.C., Fabris, J.D. & Gusevskaya, E.V. (2011) Cobalt iron magnetic composites as heterogeneous catalysts for the aerobic oxidation of thiols under alkali free conditions. Applied Catalysis A: General, 392, 151–157.Google Scholar
Moodley, P., Scheijen, F.J.E., Niemantsverdriet, J.W. & Thune, P.C. (2010) Iron oxide nanoparticles on flat oxidic surfaces – introducing a new model catalyst for Fischer-Tropsch catalysis. Catalysis Today, 154, 142–148.CrossRefGoogle Scholar
Moura, F.C.C., Araujo, M.H., Costa, R.C.C., Fabris, J.D., Ardisson, J.D., Macedo, W.A.A. & Lago, R.M. (2005) Efficient use of Fe metal as an electron transfer agent in a heterogeneous Fenton system based on Fe0/ Fe3O4 composites. Chemosphere, 60, 1118–1123.Google Scholar
Moura, F.C.C., Araujo, M., Dalmázio, I., Alves, T.M.A. Santos, L.S., Eberlin, M.N. Augusti, R. & Lago, R.M. (2006) Investigation of reaction mechanisms by electrospray ionization mass spectrometry: characterization of intermediates in the degradation of phenol by a novel iron/magnetite/hydrogen peroxide heterogeneous oxidation system. Rapid Communications in Mass Spectrometry, 20, 1859–1863.Google Scholar
Nejad, M.A. & Jonsson, M. (2004) Reactivity of hydrogen peroxide towards Fe3O4, Fe2CoO4 and Fe2NiO4 . Journal of Nuclear Materials, 334, 28–34.Google Scholar
Nguyen, T.D., Phan, N.H., Do, M.H. & Ngo, K.T. (2011) Magnetic Fe2MO4 (M:Fe, Mn) activated carbons: fabrication, characterization and heterogeneous Fenton oxidation of methyl orange. Journal of Hazardous Materials, 185, 653–661.Google Scholar
Oliveira, L.C.A., Gonçalves, M., Oliveira, D.Q.L., Guarieiro, A.L.N. & Pereira, M.C. (2007a) Síntese e propriedades catalíticas em reações de oxidação de goethitas contendo nióbio. Química Nova, 30, 925–929.Google Scholar
Oliveira, L.C.A., Gonçalves, M., Guerreiro, M.C., Ramalho, T.C., Fabris, J.D., Pereira, M.C. & Sapag, K. (2007b) A new catalyst material based on niobia/iron oxide composite on the oxidation of organic contaminants in water via heterogeneous Fenton mechanisms. Applied Catalysis A: General, 316, 117–124.Google Scholar
Oliveira, L.C.A., Ramalho, T.C., Souza, E.F., Gonçalves, M., Oliveira, D.Q.L., Pereira, M.C. & Fabris, J.D. (2008) Catalytic properties of goethite prepared in the presence of Nb on oxidation reactions in water: Computational and experimental studies. Applied Catalysis B: Environmental, 83, 169–176.CrossRefGoogle Scholar
Panda, N., Sahoo, H. & Mohapatra, S. (2011) Decolourization of methyl orange using Fenton-like mesoporous Fe2O3–SiO2 composite. Journal of Hazardous Materials, 185, 359–365.Google Scholar
Pereira, M.C., Tavares, C.M., Fabris, J.D., Lago R, M., Murad, E. & Criscuolo, P.S.R. (2007) Characterization of a tropical soil and a waste from kaolin mining and their suitability as heterogeneous catalysts for Fenton and Fenton-like reactions. Clay Minerals, 42, 299–306.Google Scholar
Pereira, M.C., Garcia, E.M., Silva, A.C., Lorençon, E., Ardisson, J.D., Murad, E., Fabris, J.D., Matencio, T., Ramalho, T.C. & Rocha, M.V.J. (2011a) Nanostructured d-FeOOH: a novel photocatalyst for water splitting. Journal of Materials Chemistry, 21, 10280–10282.Google Scholar
Pereira, M.C., Cavalcante, L.C.D., Magalhães, F., Fabris, J.D., Stucki, J.W., Oliveira, L.C.A. & Murad, E. (2011b) Composites prepared from natural iron oxides and sucrose: A highly reactive system for the oxidation of organic contaminants in water. Chemical Engineering Journal, 166, 962–969.Google Scholar
Pinto, I.S.X., Pacheco, P.H.V.V., Coelho, J.V., Lorençon, E., Ardisson, J.D. Fabris, J.D., de Souza, P.P., Krambrock, K.W.H., Oliveira, L.C.A. & Pereira, M.C. (2012) Nanostructured d-FeOOH: An efficient Fenton-like catalyst for the oxidation of organics in water. Applied Catalysis B: Environmental, 119-120, 175–182.Google Scholar
Prucek, R., Hermanek, M. & Zbořil, R. (2009) An effect of iron(III) oxides crystallinity on their catalytic efficiency and applicability in phenol degradation – a competition between homogeneous and heterogeneous catalysis. Applied Catalysis A: General, 366, 325–332.Google Scholar
Ramirez, J.H., Costa, C.A., Madeira, L.M., Mata, G., Vicente, M.A., Rojas-Cervantes, M.L., López-Peinado, A.J. & Martín-Aranda, R.M. (2007) Fenton-like oxidation of Orange II solutions using heterogeneous catalysts based on saponite clay. Applied Catalysis B: Environmental, 71, 44–56.CrossRefGoogle Scholar
Rodriguez, E.M. Fernandez, G., Alvarez, P.M. Hernandez, R., Beltran, F.J. (2011) Photocatalytic degradation of organics in water in the presence of iron oxides: effects of pH and light source. Applied Catalysis B: Environmental, 102, 572–583.Google Scholar
Rosen, G.M., Tsai, P., Barth, E.D., Dorey, G., Casara, P., Spedding, M. & Halpern, H.J. (2000) A one-step synthesis of 2-(2-Pyridyl)-3H-indol-3-one N-oxide: is it an efficient spin trap for hydroxyl radical ? Journal of Organic Chemistry, 65, 4460–4463.Google Scholar
Schüle, A., Shekhah, O., Ranke, W., Schlögl, R. & Kolios, G. (2005) Microkinetic modelling of the dehydrogenation of ethylbenzene to styrene over unpromoted iron oxides. Journal of Catalysis, 231, 172180.Google Scholar
Schwertmann, U., Friedl, J. & Kyek, A. (2004) Formation and properties of a continuous crystallinity series of synthetic ferrihydrites (2- to 6-line) and their relation to FeOOH forms. Clays and Clay Minerals, 52, 221–226.Google Scholar
Shin, S., Yoon, H. & Jang, J. (2008) Polymer-encapsulated iron oxide nanoparticles as highly efficient Fenton catalysts. Catalysis Communications, 10, 178–182.CrossRefGoogle Scholar
Silva, A.C., Oliveira, D.Q.L., Oliveira, L.C.A., Anastácio, A.S., Ramalho, T.C., Lopes, J.H., Carvalho, H.W.P. & Torres, C.E.R. (2009) Nb-containing hematites Fe2–xNbxO3: The role of Nb5+ on the reactivity in presence of the H2O2 or ultraviolet light. Applied Catalysis A: General, 357, 79–84.CrossRefGoogle Scholar
Silva, A.C., Cepera, R.M., Pereira, M.C., Lima, D.Q., Fabris, J.D. & Oliveira, L.C.A. (2011) Heterogeneous catalyst based on peroxo-niobium complexes immobilized over iron oxide for organic oxidation in water. Applied Catalysis B: Environmental, 107, 237–244.Google Scholar
Souza, W.F., Guimarães, I.R., Lima, D.Q., Silva, C.L.T. & Oliveira, L.C.A. (2009) Brazilian limonite for the oxidation of quinoline: high activity after a simple magnetic separation. Energy & Fuels, 23, 4426–4430.Google Scholar
Sreethawong, T. & Chavadej, S. (2011) Color removal of distillery wastewater by ozonation in the absence and presence of immobilized iron oxide catalyst. Journal of Hazardous Materials, 155, 486–493.Google Scholar
Sun, S.P. & Lemley, A.T. (2011) p-Nitrophenol degradation by a heterogeneous Fenton-like reaction on nano-magnetite: process optimization, kinetics, and degradation pathways. Journal of Molecular Catalysis A: Chemical, 349, 71–79.Google Scholar
Teel, A.L., Warberg, C.R., Atkinson, D.A. & Watts, R.J. (2001) Comparison of mineral and soluble iron Fenton's catalysts for the treatment of trichloroethylene. Water Research, 35, 977–984.Google Scholar
Valdés-Solís, T., Valle-Vigón, P., Álvarez, S., Marbán, G. & Fuertes, A.B. (2007) Manganese ferrite nanoparticles synthesized through a nanocasting route as a highly active Fenton catalyst. Catalysis Communications, 8, 2037–2042.Google Scholar
Vicente, F., Rosas, J.M., Santos, A. & Romero, A. (2011) Improvement soil remediation by using stabilizers and chelating agents in a Fenton-like process. Chemical Engineering Journal, 172, 689–697.Google Scholar
Villa, R.D. & Nogueira, R.F.P. (2006) Oxidation of p,p’- DDT and p,p’-DDE in highly and long-term contaminated soil using Fenton reaction in a slurry system. Science of the Total Environment, 371, 11–18.Google Scholar
Voinov, M.A., Pagán, J.O.S., Morrison, E., Smirnova, T.I. & Smirnov, A.I. (2011) Surface-mediated production of hydroxyl radicals as a mechanism of iron oxide nanoparticle biotoxicity. Journal of the American Chemical Society, 133, 35–41.Google Scholar
Watts, R.J., Foget, M.K., Kong, S.H. & Teel, A.L. (1999) Hydrogen peroxide decomposition in model subsurface systems. Journal of Hazardous Materials B, 69, 229–243.Google Scholar
Wu, J.J., Muruganandham, M., Yang, J.S. & Lin, S.S. (2006) Oxidation of DMSO on goethite catalyst in the presence of H2O2 at neutral pH. Catalysis Communications, 7, 901–906.Google Scholar
Xing, S., Zhou, Z., Ma, Z. & Wu, Y. (2011) Characterization and reactivity of Fe3O4/FeMnOx core/shell nanoparticles for methylene blue discoloration with H2O2 . Applied Catalysis B: Environmental, 107, 386–392.CrossRefGoogle Scholar
Xu, H.Y. Prasad, M., Liu, Y (2009) Schorl: a novel catalyst in mineral-catalyzed Fenton-like system for dyeing wastewater discoloration. Journal of Hazardous Materials, 165, 1186–1192.Google Scholar
Xue, X., Hanna, K., Abdelmoula, M. & Deng, N. (2009a) Adsorption and oxidation of PCP on the surface of magnetite: kinetic experiments and spectroscopic investigations. Applied Catalysis B: Environmental, 89, 432–440.Google Scholar
Xue, X., Hanna, K., Despas, C., Wub, F. & Deng, N. (2009b) Effect of chelating agent on the oxidation rate of PCP in the magnetite/H2O2 system at neutral pH. Journal of Molecular Catalysis A: Chemical, 311, 29–35.Google Scholar
Yang, S., He, H., Wu, D., Chen, D., Ma, Y., Li, X., Zhu, J. & Yuan, P. (2009a) Degradation of methylene blue by heterogeneous Fenton reaction using titanomagnetite at neutral pH values: process and affecting factors. Industrial Engineering and Chemical Research, 48, 9915–9921.Google Scholar
Yang, S., He, H., Wu, D., Chen, D., Liang, X., Qin, Z., Fan, M., Zhu, J. & Yuan, P. (2009b) Decolorization of methylene blue by heterogeneous Fenton reaction using Fe3-xTixO4 (0 ⩽ x ⩽ 0.78) at neutral pH values. Applied Catalysis B: Environmental, 89, 527–535.CrossRefGoogle Scholar
Yaping, Z, Jiangyong, H. & Hongbin, C. (2010) Elimination of estrogen and its estrogenicity by heterogeneous photo-Fenton catalyst β-FeOOH/resin. Journal of Photochemistry and Photobiology A: Chemistry, 212, 94–100.Google Scholar
Yeh, C.K.J., Hsu, C.Y., Chiu, C.H. & Huang, K.L. (2008) Reaction efficiencies and rate constants for the goethite-catalyzed Fenton-like reaction of NAPLform aromatic hydrocarbons and chloroethylenes. Journal of Hazardous Materials, 151, 562–569.Google Scholar
Yip, A.C.K., Lam, F.L.Y. & Hu, X. (2005) Chemicalvapor- deposited copper on acid-activated bentonite clay as an applicable heterogeneous catalyst for the photo-Fenton-like oxidation of textile organic pollutants. Industrial & Engineering Chemistry Research, 44, 7983–7990.Google Scholar
Zhang, S., Zhao, X., Niu, H., Shi, Y., Cai, Y. & Jiang, G. (2009) Superparamagnetic Fe3O4 nanoparticles as catalysts for the catalytic oxidation of phenolic and aniline compounds. Journal of Hazardous Materials, 167, 560–566.Google Scholar