57
permanganate as an oxidant for in situ
oxidation of trichloroethylene-contaminated
groundwater: A laboratory and kinetics study,
J. Hazard. Mater., 153 (2008) 919–927.
[12] J.A. Khan, X. He, H.M. Khan, N.S. Shah,
D.D. Dionysiou, Oxidative degradation of
atrazine in aqueous solution by UV/H
2
O
2
/
Fe
2+
, UV/S
2
O
8
2-
/Fe
2+
and UV/HSO
5-
/Fe
2+
processes: A comparative study, Chem. Eng.
J., 218 (2013) 376–383.
[13] K. Ayoub, E.D. van Hullebusch, M. Cassir, A.
Bermond, Application of advanced oxidation
processes for TNT removal: A review, J.
Hazard. Mater., 178 (2010) 10-28.
[14] M. Bellardita, V. Loddo, A. Mele, W.
Panzeri, F. Parrino, I. Pibiri, L. Palmisano,
Photocatalysis in dimethyl carbonate green
solvent: Degradation and partial oxidation of
phenanthrene on supported TiO
2
, RSC Adv.,
4 (2014) 40859–40864.
[15] M. Ruokolainen, T. Gul, H. Permentier,
T. Sikanen, R. Kostiainen, T. Kotiaho,
Comparison of TiO
2
photocatalysis,
electrochemically assisted Fenton reaction
and direct electrochemistry for simulation of
phase metabolism reactions of drugs, Eur. J.
Pharm. Sci., 83 (2016) 36–44.
[16] S.N. Malik, P.C. Ghosh, A.N. Vaidya, S.N.
Mudliar, Hybrid ozonation process for
industrial wastewater treatment: Principles
and applications: A review, J. Water Process
Eng., 35 (2020) 101193.
[17] K. Ayoub, E.D. Van Hullebusch, M. Cassir, A.
Bermond, Application of advanced oxidation
processes for TNT removal: A review, J.
Hazard. Mater., 178 (2010) 10–28.
[18] M.D. Nicodemos Ramos, L.A. Sousa, A.
Aguiar, Effect of cysteine using Fenton
processes on decolorizing different dyes: a
kinetic study, Environ. Technol., 57 (2020)
1–132.
[19] C.M. Dominguez, A. Romero, A. Santos,
Selective removal of chlorinated organic
compounds from lindane wastes by
combination of nonionic surfactant soil
ushing and Fenton oxidation, Chem. Eng.
J., 376 (2019) 120009.
[20] C.G.S. Lima, N.M. Moreira, M.W. Paixão,
A.G. Corrêa, Heterogenous green catalysis:
Application of zeolites on multicomponent
reactions, Curr. Opin. Green Sustain.
Chem., 15 (2019) 1-7.
[21] P.T. Silva, V.L. da Silva, B. de B. Neto, M.O.
Simonnot, Phenanthrene and pyrene oxidation
in contaminated soils using Fenton’s reagent,
J. Hazard. Mater., 161 (2009) 967–973.
[22] F. Pardo, M. Peluffo, A. Santos, A. Romero,
Optimization of the application of the
Fenton chemistry for the remediation of a
contaminated soil with polycyclic aromatic
hydrocarbons, J. Chem. Technol. Biotechnol.,
91 (2016) 1763–1772.
[23] G. Vilardi, D. Sebastiani, S. Miliziano, N.
Verdone, L. Di Palma, Heterogeneous nZVI-
induced Fenton oxidation process to enhance
biodegradability of excavation by-products,
Chem. Eng. J., 335 (2018) 309–320.
[24] E.G. Garrido-Ramírez, B.K.G. Theng, M.L.
Mora, Clays and oxide minerals as catalysts
and nanocatalysts in Fenton-like reactions - A
review, Appl. Clay Sci., 47 (2010) 182–192.
[25] Y. Wang, Y. Gao, L. Chen, H. Zhang, Goethite
as an efcient heterogeneous Fenton catalyst
for the degradation of methyl orange, Catal.
Today, 252 (2015) 107–112.
[26] M. Lu, Z. Zhang, W. Qiao, Y. Guan, M. Xiao,
C. Peng, Removal of residual contaminants
in petroleum-contaminated soil by Fenton-
like oxidation, J. Hazard. Mater., 179 (2010)
604–611.
[27] M. Munoz, Z.M. de Pedro, J.A. Casas,
J.J. Rodriguez, Preparation of magnetite-
based catalysts and their application in
heterogeneous Fenton oxidation - A review,
Appl. Catal. B: Environ., 176 (2015) 249-
265.
[28] S. Rostamnia, B. Gholipour, X. Liu, Y.
Wang, H. Arandiyan, NH
2
-coordinately
immobilized tris(8-quinolinolato)iron onto
the silica coated magnetite nanoparticle:
Anthracene removal from soils by Fe3O4-Fenton process Mahdia Hamidinasab et al