References

1. W.K. Lafi, B. Shannak, M. Al-Shannag, Z. Al-Anber, M. Al-Hasan, Treatment of olive mill wastewater by combined advanced oxidation and biodegradation, Sep. Purif. Technol., 70 (2009) 141–146.
2. M.J.B. Juárez, A. Zafra-Gó Mez, B. Luzó N-Toro, O.A. Ballesteros-García, A. Navaló N A, J. González, J.L. Vílchez, Gas chromatographic–mass spectrometric study of the degradation of phenolic compounds in wastewater olive oil by Azotobacter Chroococcum, Biosour. Technol., 99 (2008) 2392–2398.
3. F.J. Benitez, J.L. Acero, J. Garcia, A.I. Leal, Purification of cork processing wastewaters by ozone, by activated sludge, and by their two sequential applications, Water Res., 37 (2003) 4081–4090.
4. A. El-Abbassi, H. Kiai, A. Hafidi, Phenolic profile and antioxidant activities of olive mill wastewater, Food Chem., 132 (2012) 406–412.
5. I. Del Castillo, P. Herná, A. Lafuente, I.D. Rodríguez-Llorente, M.A. Caviedes, E. Pajuelo, Self-bioremediation of cork-processing wastewaters by (chloro)phenol-degrading bacteria immobilised onto residual cork particles, Water Res., 46 (2012) 1723–1734.
6. E. Mendonça, A. Picado, L. Silva, A. Anselmo, Ecotoxicological evaluation of cork-boiling wastewaters, Ecotoxicol. Environ. Saf., 66 (2007) 384–390.
7. N. De La Cruz, J. Giménez, S. Esplugas, D. Grandjean, L.F. Alencastro, C. Pulgarín, Degradation of 32 emergent contaminants by UV and neutral photo-fenton in domestic wastewater effluent previously treated by activated sludge, Water Res., 46 (2012) 1947–1957.
8. A. Bojanowska-Czajka, H. Nichipor, P. Drzewicz, B. Szostek, A. Gałezowska, S. Meczynska, M. Kruszewski, Z. Zimek, G. Nałecz-Jawecki, M. Trojanowicz, Radiolytic decomposition of pesticide carbendazim in waters and wastes for environmental protection, J. Radioanal. Nucl. Chem., 289 (2011) 303–314.
9. M. Zhou, J. He, Degradation of azo dye by three clean advanced oxidation processes: Wet oxidation, electrochemical oxidation and wet electrochemical oxidation—a comparative study, Electrochim. Acta, 53 (2007) 1902–1910.
10. S.M. Ghoreishian, S.M. Kang, G. Seeta Rama Raju, M. Norouzi, S.C. Jang, H.J. Yun, S.T. Lim, Y.K. Han, C. Roh, Y.S. Huh, γ-Radiolysis as a highly efficient green approach to the synthesis of metal nanoclusters: a review of mechanisms and applications, Chem. Eng. J., 360 (2019) 1390–1406.
11. L. Wojnárovits, Radiation Chemistry, in: A. Vértes, S. Nagy, Z. Klencsár, R.G. Lovas, F. Rösch, Eds., Handbook of Nuclear Chemistry, Springer, Boston, MA, 2011, pp. 1263–1331.
12. O. Chedeville, M. Debacq, C. Porte, Removal of phenolic compounds present in olive mill wastewaters by ozonation, Desalination. 249 (2009) 865–869.
13. A.C. Gomes, L. Silva, R. Simões, N. Canto, A. Albuquerque, Toxicity reduction and biodegradability enhancement of cork processing wastewaters by ozonation, Water Sci. Technol., 68 (2013) 2214–2219.
14. P. Cañizares, J. Lobato, R. Paz, M.A. Rodrigo, C. Sáez, Advanced oxidation processes for the treatment of olive-oil mills wastewater, Chemosphere, 67 (2007) 832–838.
15. M. Dias-Machado, L.M. Madeira, B. Nogales, O.C. Nunes, Treatment of cork boiling wastewater using chemical oxidation and biodegradation, Chemosphere, 64 (2006) 455–461.
16. F.J. Benítez, J.L. Acero, A.I. Leal, Treatment of wastewaters from the cork process industry by using ultrafiltration membranes, Desalination, 229 (2008) 156–169.
17. V. Sygouni, A.G. Pantziaros, I.C. Iakovides, E. Sfetsa, P.I. Bogdou, E.A. Christoforou, C.A. Paraskeva, Treatment of Two-phase olive mill wastewater and recovery of phenolic compounds using membrane technology, Membranes (Basel), 9 (2019) 27.
18. M. Gotsi, N. Kalogerakis, E. Psillakis, P. Samaras, D. Mantzavinos, Electrochemical oxidation of olive oil mill wastewaters, Water Res., 39 (2005) 4177–4187.
19. F.J. Benítez, J.L. Acero, A.I. Leal, F.J. Real, Ozone and membrane filtration based strategies for the treatment of cork processing wastewaters, J. Hazard. Mater., 152 (2008) 373–380.
20. E. De Torres-Socías, I. Fernández-calderero, I. Oller, M.J. Trinidad-lozano, F.J. Yuste, S. Malato, Cork boiling wastewater treatment at pilot plant scale: comparison of solar photo- Fenton and ozone (O3, O3/H2O2). Toxicity and biodegradability assessment, Chem. Eng. J., 234 (2013) 232–239.
21. A. Fiorentino, A. Gentili, M. Isidori, M. Lavorgna, A. Parrella, F. Temussi, Olive Oil Mill Wastewater Treatment Using a Chemical and Biological Approach, J. Agric. Food Chem., 52 (2004) 5151–5154.
22. K. Baransi, Y. Dubowski, I. Sabbah, Synergetic effect between photocatalytic degradation and adsorption processes on the removal of phenolic compounds from olive mill wastewater, Water Res., 46 (2012) 789–798.
23. W.K. Lafi, M. Al-Anber, Z.A. Al-Anber, M. Al-shannag, A. Khalil, Coagulation and advanced oxidation processes in the treatment of olive mill wastewater (OMW), Desal. Wat. Treat., 24 (2010) 251–256.
24. S. Cabo Verde, T. Silva, P. Matos, Effects of gamma radiation on wastewater microbiota, Radiat. Environ. Biophys., 55 (2015) 125–131.
25. R. Melo, S. Cabo Verde, J. Branco, M.L. Botelho, Gamma radiation induced effects on slaughterhouse wastewater treatment, Radiat. Phys. Chem., 77 (2008) 98–100.
26. C. Lima, J. Madureira, R. Melo, M.M. Carolino, J.P. Noronha, F.M.A. Margaça, S. Cabo Verde, A biodegradation bench study of cork wastewater using gamma radiation, J. Adv. Oxid. Technol., 19 (2016) 73–78.
27. F.J. Benitez, J. Beltran-Heredia, J.L. Acero, M.L. Pinilla, Simultaneous photodegradation and ozonation plus UV radiation of phenolic acids — major pollutants in agro-industrial wastewaters, J. Chem. Technol. Biotechnol., 70 (1997) 253–260.
28. F.J. Benitez, F.J. Real, J.L. Acero, A.I. Leal, C. Garcia, Gallic acid degradation in aqueous solutions by UV/H₂O₂ treatment, Fenton’s reagent and the photo-Fenton system., J. Hazard. Mater., 126 (2005) 31–39.
29. R.P. Melo, J.P. Leal, M.L. Botelho, Radiolytic degradation mechanism of gallic acid and its end-products, Rapid Commun. Mass Spectrom., 25 (2011) 218–222.
30. J. Madureira, L. Barros, R. Melo, S.C. Verde, I.C.F.R. Ferreira, F.M.A. Margaça, Degradation of phenolic acids by gamma radiation as model compounds of cork wastewaters, Chem. Eng. J., 341 (2018) 227–237.
31. C.J. Philippopoulos, M.D. Nikolaki, Photocatalytic Processes on the Oxidation of Organic Compounds in Water, in: Blandna Ramov, Ed., New Trends Technol., InTech, InTech, 2010.
32. J.L. Acero, J.F. Benitez, F.J. Real, A.I. Leal, A. Sordo, F.J. Benitez, Oxidation of esculetin, a model pollutant present in cork processing wastewaters by chemical methods, Ozone Sci. Eng., 27 (2005) 317–326.
33. R. Melo, Application of Ionizing Radiation to Persistent Organic Pollutants Decomposition (Doctoral dissertation), Universidade de Lisboa, 2012.
34. A. Noubigh, M. Abderrabba, E. Provost, Temperature and salt addition effects on the solubility behaviour of some phenolic compounds in water, J. Chem. Thermodyn., 39 (2007) 297–303.
35. G. V Buxton, C.L. Greenstock, W.P. Helman, A.B. Ross, Critical review of rate constants for reactions of hydrated electrons, hydrogen atoms and hydroxyl radicals (•OH/•O^–) in aqueous solution, J. Phys. Chem. Ref. Data, 17 (1988) 513–886.
36. American Society for Testing and Materials, Practice for Using the Fricke Reference Standard Dosimetry System, 12.02, Philadelphia, PA, 1992.
37. R.G. Zepp, W.M. Sheldon, M.A. Moran, Dissolved organic fluorophores in southeastern US coastal waters: correction method for eliminating Rayleigh and Raman scattering peaks in excitation–emission matrices EEM analysis with careful scatter correction can provide a powerful tool for evaluating pathways for carbon cycling in estuaries, Mar. Chem., 89 (2004) 15–36.
38. B. Razavi, W. Song, H. Santoke, W.J. Cooper, Treatment of statin compounds by advanced oxidation processes: kinetic considerations and destruction mechanisms, Radiat. Phys. Chem., 80 (2011) 453–461.
39. I.G. Antropova, A.A. Fenina, A.A. Revina, Radiation-Chemical Transformations of Coumarins in Organic Solvents, High Energy Chem., 41 (2007) 61–64.
40. S.P. Mezyk, T.J. Neubauer, W.J. Cooper, J.R. Peller, Free-radicalinduced oxidative and reductive degradation of sulfa drugs in water: absolute kinetics and efficiencies of hydroxyl radical and hydrated electron reactions, J. Phys. Chem., 111 (2007) 9019–9024.
41. G. Louit, S. Foley, J. Cabillic, F. Taran, A. Valleix, J. Philippe Renault, S. Pin, The reaction of coumarin with the OH radical revisited: hydroxylation product analysis determined by fluorescence and chromatography, Radiat. Phys. Chem., 72 (2005) 119–124.
42. D.G. Crosby, R.V. Berthold, Fluorescence spectra of some simple coumarins, Anal. Biochem., 4 (1962) 349–357.