Removal of basic and industrial azo reactive dyes from aqueous solutions via Fenton-like reactions using catalytic non-magnetic Pd-flyash and magnetic Pd-Fe3O4-flyash composite particles

Separation and Purification Technology

Volumn 172, Issue , 2017, Pages 338-349

  Narayani, Harsha ^a,b   Augustine, Rimesh ^a,e   Sumi, S ^a   Jose, Manu ^a,b   Deepa Nair, K ^c   Samsuddin, M ^c   Prakash, Halan ^d   Shukla, Satyajit ^a,b  

^a REGIONAL RESEARCH LABORATORY CSIR   (India)

^b ACADEMY OF SCIENTIFIC AND INNOVATIVE RESEARCH ACSIR   (India)

^c CENTRE FOR EARTH SCIENCE STUDIES   (India)

^d BIRLA INSTITUTE OF TECHNOLOGY AND SCIENCE   (India)

^e Pusan National University   (South Korea)

Author keywords

Advanced oxidation process; Hydroxyl radical; Magnetic separation; Nanoparticles; Organic synthetic dye

Indexed keywords

ACTIVATED CARBON; ACTIVATED CARBON TREATMENT; ADSORPTION; CATALYSTS; CHEMICAL OXYGEN DEMAND; COMPOSITE MATERIALS; CONDUCTING POLYMERS; DYES; LEACHING; MAGNETIC BUBBLES; MAGNETIC SEPARATION; MAGNETISM; NANOMAGNETICS; NANOPARTICLES; OXIDATION; OXIDATION RESISTANCE; PRECIPITATION (CHEMICAL); SILVER; SOLUTIONS; STRIPPING (DYES);

ADVANCED OXIDATION PROCESS; ADVANCED OXIDATION PROCESSES; CATALYST CONCENTRATION; FENTON-LIKE REACTIONS; HIGH SURFACE AREA ACTIVATED CARBON; HYDROXYL RADICALS; INTERMEDIATE PRODUCT; SYNTHETIC DYES;

PALLADIUM;

EID: 84986612924     PISSN: 13835866     EISSN: 18733794     Source Type: Journal    
DOI: 10.1016/j.seppur.2016.08.027     Document Type: Article

References (33)

1. [1] S. Shukla, K.G.K. Warrier, B.K. Babu, A process for decomposition of organic synthetic-dyes using semiconductor-oxides nanotubes via dark-catalysis, World Intellectual Property Organization (WIPO) Publication Number WO/2014/027364, Publication Date: 20-February-2014.
2. [2] Shukla, S., Oturan, M.A., Dye removal using electrochemistry and semiconductor oxide nanotubes. Environ. Chem. Lett. 13 (2015), 157–172.
3. [3] Jose, M., Haridas, M.P., Shukla, S., Predicting dye-adsorption capacity of hydrogen titanate nanotubes via one-step dye-removal method of novel chemically-activated catalytic process conducted in dark. J. Environ. Chem. Eng. 2 (2014), 1980–1988.
4. [4] Babu, B.K., Warrier, K.G.K., Shukla, S., Decoloration of aqueous solution containing organic synthetic-dye via dark-catalysis process using hydrothermally synthesized semiconductor-oxides nanotubes. Adv. Sci., Eng. Med. 6 (2014), 173–183.
5. [5] Lorencon, E., Brandao, F.D., Krambrock, K., Alves, D.C.B., Silva, J.C.C., Ferlauto, A., Lago, R.M., Generation of reactive oxygen species in titanates nanotubes induced by hydrogen peroxide and their application in catalytic degradation of methylene blue dye. J. Mol. Catal. A 394 (2014), 316–323.
6. [6] Zhou, C., Luo, J., Chen, Q., Jiang, Y., Dong, X., Cui, F., Titanate nanosheets as highly efficient non-light-driven catalysts for degradation of organic dyes. Chem. Commun. 51 (2015), 10847–10849.
7. [7] Zazo, J.A., Casas, J.A., Mohedano, A.F., Gilarranz, M.A., Rodriguez, J.J., Chemical pathways and kinetics of phenol oxidation by Fenton's reagent. Environ. Sci. Technol. 39 (2005), 9295–9302.
8. [8] Dhakshinamoorthy, A., Navalon, S., Alavaro, M., Gracia, H., Metal nanoparticles as heterogeneous Fenton catalysts. Chem. Sus. Chem. 5 (2012), 46–64.
9. [9] Gil-Lozano, C., Losa-Adams, E., Davila, A.F., Gago-Duport, L., Pyrite nanoparticles as a Fenton-like reagent for in situ remediation of organic pollutants. Beilstein J. Nanotechnol. 5 (2014), 855–864.
10. 3 catalysts. Chem. Commun., 2008, 3885–3887.
11. [11] Yalfani, M.S., Contreras, S., Medina, F., Sueiras, J., Phenol degradation by Fenton's process using catalytic in situ generated hydrogen peroxide. Appl. Catal. B 89 (2009), 519–526.
12. 3 nanoparticles in SBA-15 for Fenton-like processes: confinement and synergistic effects. Appl. Catal. B 165 (2015), 79–86.
13. [13] Shukla, S., Seal, S., Akesson, J., Oder, R., Carter, R., Rahman, Z., Study of mechanism of electroless copper coating of fly-ash cenosphere particles. Appl. Surf. Sci. 181 (2001), 35–50.
14. 4 catalysts for phenol degradation using peroxymonosulfate. RSC Adv. 2 (2012), 5645–5650.
15. [15] Shukla, S., Seal, S., Electroless copper coating of zirconia utilizing palladium catalyst. J. Am. Ceram. Soc. 86 (2003), 279–285.
16. [16] Cheng, J.P., Ma, R., Chen, X., Shi, D., Liu, F., Zhang, X.B., Effect of ferric ions on the morphology and size of magnetitie nanocrystals synthesized by ultrasonic irradiation. Crys. Res. Technol. 46 (2011), 723–730.
17. [17] Rice, E.W., Baird, R.B., Eaton, A.D., Clesceri, L.S., (eds.) Standard Methods for the Examination of Water and Wastewater, 22nd ed., 2012, American Public Health Association, Washington.
18. 3 magnetic photocatalyst undergoing photo-dissolution process without silica interlayer. Catal. Lett. 143 (2013), 807–816.
19. 2 photocatalyst. J. Photochem. Photobiol. A 134 (2000), 139–142.
20. 2 and some ions. Langmuir 18 (2002), 3247–3254.
21. [21] Ang, L.-M., Andy Hor, T.S., Xu, G.-Q., Tung, C.H., Zhao, S., Wang, J.L.S., Electroless plating of metals onto carbon nanotubes activated by a single-step activation method. Chem. Mater. 11 (1999), 2115–2118.
22. 2 in advanced oxidation processes. J. Hazard. Mater. 275 (2014), 121–135.
23. 2 destruction in presence of hydrogen. Appl. Catal. A 332 (2007), 70–78.
24. 2 produced by water electrolysis for the efficient electro-fenton degradation of Rhodamine B. Environ. Sci. Technol. 45 (2011), 8514–8520.
25. [25] Baiju, K.V., Shukla, S., Sandhya, K.S., James, J., Warrier, K.G.K., Photocatalytic activity of sol-gel-derived nanocrystalline titania. J. Phys. Chem. C 111 (2007), 7612–7622.
26. [26] Lachheb, H., Puzenat, E., Houas, A., Ksibi, M., Elaloui, E., Guillard, C., Herrmann, J.M., Photocatalytic degradation of various types of dyes (Alizarin S, Crocein Orange G, Methyl Red, Congo Red, Methylene Blue) in water by UV-irradiated titania. Appl. Catal. B 39 (2002), 75–90.
27. [27] Aber, S., Sheydaei, M., Removal of COD from industrial effluent containing indigo dye using adsorption method by activated carbon cloth: optimization, kinetic, and isotherm studies. Clean – Soil Air Water 40 (2012), 87–94.
28. [28] Bansode, R.R., Losso, J.N., Marshall, W.E., Rao, R.M., Portier, R.J., Pecan shell-based granular activated carbon for treatment of chemical oxygen demand (COD) in municipal wastewater. Bioresource Technol. 94 (2004), 129–135.
29. [29] Jeong, J., Yoon, J., pH effect of OH radical production in photo/ferrioxalate system. Water Res. 39 (2005), 2893–2900.
30. [30] Cruz-Gonzalez, K., Torres-Lopez, O., García-Leon, A., Guzman-Mar, J.L., Reyes, L.H., Hernandez-Ramírez, A., Peralta-Hernandez, J.M., Determination of optimum operating parameters for Acid Yellow 36 decoloration by electro-Fenton process using BDD cathode. Chem. Eng. J. 160 (2010), 199–206.
31. 7 nanotubes structure as a magnetically recyclable dye-removal catalyst. RSC Adv. 5 (2014), 30354–30362.
32. [32] Thazhe, L., Shereef, A., Shukla, S., Reshmi, C.P., Varma, M.R., Suresh, K.G., Patil, K., Warrier, K.G.K., Magnetic dye-adsorbent catalyst: processing, characterization, and application. J. Am. Ceram. Soc. 93 (2010), 3642–3650.
33. [33] Panias, D., Taxiarchou, M., Paspaliaris, I., Konotpoulos, A., Mechanism of dissolution of iron oxides in aqueous oxalic acid solutions. Hydrometallurgy 42 (1996), 257–265.