[1] Kokkinos P.,Mantzavinos D.,Venieri D. .2020 .Current trends in the application of nanomaterials for the removal of emerging micropollutants and pathogens from water. Molecules, 25 : .
[2] Gomes J.,Frasson D.,Quinta-Ferreira R. M.,Matos A.,Martins R. C. .2019 .Removal of enteric pathogens from real wastewater using single and catalytic ozonation. Water, 11(127) : .
[3] Wang W.,Wang H.,Li G.,An T.,Zhao H.,Wong P. K. .2019 .Catalyst-free activation of persulfate by visible light for water disinfection: efficiency and mechanisms, Water Res. , 157(106) : .
[4] Tulchinsky T. H. .2018 .cholera, the Broad Street pump; waterborne diseases then and now. Case Stud. Public Health, 77 : .
[5] Paździor K.,Bilińska L.,Ledakowicz S. .2019 .A review of the existing and emerging technologies in the combination of AOPs and biological processes in industrial textile wastewater treatment, Chem. , 376(120597) : .
[6] Kokkinos P. A.,Galanis A.,Vantarakis A. .2011 .Molecular detection of multiple viral targets in untreated urban sewage from Greece, Virol. , 8(195) : .
[7] Jacangelo J. G.,Trussell R. R. .2002 .International report: water and wastewater disinfection - trends, issues and practices. Water Supply, 2(147) : .
[8] Feitz A. .2005 .Advanced oxidation processes and industrial wastewater treatment. Water, 32(59) : .
[9] Sgroi M.,Anumol T.,Vagliasindi F. G. A.,Snyder S. A.,Roccaro P. .2021 .Comparison of the new Cl₂/O₃/UV process with different ozone- and UVbased AOPs for wastewater treatment at pilot scale: removal of pharmaceuticals and changes in fluorescing organic matter. Sci. Total, 765(142720) : .
[10] Lai C.,Liu X.,Huo X.,An Z.,Li L.,Fu Y.,Li B.,Zhang M.,Liu S.,Yang L. .2021 .Critical review of advanced oxidation processes in organic wastewater treatment. Chemosphere, 275(130104) : .
[11] Ikehata K.,Li Y.,Ameta S. C.,Ameta R. .2018 .Chapter 5 - Ozone-based processes, in Advanced Oxidation Processes for Waste Water Treatment. , 115 : .
[12] Otieno B.,Apollo S.,Naidoo B.,Ochieng A. .2019 .Modeling ozonation pretreatment parameters of distillery wastewater for improved biodegradability. J. Environ. Sci. Health Part A, 54(1066) : .
[13] Singh P.,Shandilya P.,Raizada P.,Sudhaik A.,Rahmani-Sani A.,Hosseini-Bandegharaei A. .2020 .Review on various strategies for enhancing photocatalytic activity of graphene-based nanocomposites for water purification. Arab. J. Chem, 13(3498) : .
[14] Wang W.,Li G.,Xia D.,An T.,Zhao H.,Wong P. K. .2017 .Photocatalytic nanomaterials for solar-driven bacterial inactivation: recent progress and challenges. Environ. Sci. Nano, 4(782) : .
[15] Fu C.,Wu Y.,Zhou J.,Zuo G.,Song Y.,Tan Y. .2019 .Ozonation reactivity characteristics of dissolved organic matter in secondary petrochemical wastewater by single ozone. , 233(34) : .
[16] J.-G. Kim A. E.,Yousef A. E. .2000 .Inactivation kinetics of foodborne spoilage and pathogenic bacteria by ozone. J. Food Sci., 65(521) : .
[17] Ding W.,Jin W.,Cao S.,Zhou X.,Wang C.,Jiang Q.,Huang H.,Tu R.,Han S.-F.,Wang Q. .2019 .Ozone disinfection of chlorine-resistant bacteria in drinking water. Water Res., 160(339) : .
[18] Jamil A.,Farooq S.,I. Hashmi S. .2017 .Ozone disinfection efficiency for indicator microorganisms at different pH values and temperatures. Ozone Sci. Eng, 39(407) : .
[19] Jamil A.,Farooq S.,I. Hashmi S. .2017 .Ozone disinfection efficiency for indicator microorganisms at different pH values and temperatures. Ozone Sci. Eng, 39(407) : .
[20] .2019 .Ozone disinfection of chlorine-resistant bacteria in drinking water,” Water Res. , 160(339) : .
[21] Jamil A.,Farooq S.,and I. Hashmi S. .2017 .Ozone disinfection efficiency for indicator microorganisms at different pH values. Ozone Sci. Eng, 39(407) : .
[22] Environ Sci. Total .2021 .Sunlight advanced oxidation processes vs ozonation for wastewater disinfection and safe reclamation,”. , 787(147531) : .
[23] Hodges B. C.,Cates E. L.,-H. Kim E. L. .2018 .Challenges and prospects of advanced oxidation water treatment processes using catalytic nanomaterials,” Nat. , 13(642) : .
[24] J. M. Sousa ,Hazard J. .2017 .“Ozonation and UV254nm radiation for the removal of microorganisms and antibiotic resistance genes from urban wastewater,”. , 323(434) : .
[25] Michael-Kordatou ,Hazard J. .2017 .On the capacity of ozonation to remove antimicrobial compounds, resistant bacteria and toxicity from urban wastewater effluents,”. , 323(414) : .
[26] Baghal F. .2021 .Performance evaluation of ozonation for removal of antibiotic-resistant Escherichia coli and Pseudomonas aeruginosa and genes from hospital wastewater. ” Sci. Rep, 11(24519) : .
[27] Nahim-Granados S.,Rivas-Ibáñez G.,Sánchez Pérez J. A.,Malato S.,M. I. S. .2020 .Polo-López, “Synthetic fresh-cut wastewater disinfection and decontamination by ozonation at pilot scale,” Water Res. , 170(115304) : .
[28] Malvestiti J. A.,Cruz-Alcalde A.,López-Vinent N.,Dantas R. F.,Sans C. .2019 .Catalytic ozonation by metal ions for municipal wastewater disinfection and simultaneous micropollutants removal. ” Appl. Catal. B Environ, 259(118104) : .
[29] Körbahti B. K.,Tanyolaç A. .2003 .Continuous electrochemical treatment of phenolic wastewater in a tubular reactor,” Water Res. , 37(1505) : .
[30] Altay U.,Koparal A. S.,Ogutveren A. S. .2008 .Complete treatment of olive mill wastewaters by electrooxidation,” Chem. , 139(445) : .
[31] C. ,Martínez-Huitle E.,Brillas E. .2009 .Decontamination of wastewaters containing synthetic organic dyes by electrochemical methods: A general review. ” Appl. Catal. B Environ, 87(105) : .
[32] C. E. Schaefer C.,Andaya C.,Urtiaga A. .2015 .Assessment of disinfection and by-product formation during electrochemical treatment of surface water using a Ti/IrO₂ anode. , 264(411) : .
[33] Á. Anglada A.,Urtiaga and I. Ortiz,Chem J. .2009 .Contributions of electrochemical oxidation to wastewater treatment: fundamentals and review of applications,”. , 84(1747) : .
[34] .2014 .Effects of anodic potential and chloride ion on overall reactivity in electrochemical reactors designed for solar-powered wastewater treatment. ” Environ. Sci. Technol, 48(2377) : .
[35] Lacasa E.,Tsolaki Z.,Sbokou M. A.,Rodrigo D.,Mantzavinos D. .2013 .Electrochemical disinfection of simulated ballast water on conductive diamond electrodes,” Chem. , 223(516) : .
[36] M. Rajab C.,Heim T.,Letzel J. E.,Drewes B.,Helmreich B. .2015 .Electrochemical disinfection using boron-doped diamond electrode - The synergetic effects of in situ ozone and free chlorine generation. , 121(47) : .
[37] Lacasa E.,Tsolaki Z.,Sbokou M. A.,Rodrigo D.,Mantzavinos D. .2013 .Electrochemical disinfection of simulated ballast water on conductive diamond electrodes,” Chem. , 223(516) : .
[38] M. Rajab C.,Heim T.,Letzel J. E.,Drewes B.,Helmreich B. .2015 .Electrochemical disinfection using boron-doped diamond electrode - The synergetic effects of in situ ozone and free chlorine generation. , 121(47) : .
[39] .2014 .Effects of anodic potential and chloride ion on overall reactivity in electrochemical reactors designed for solar-powered wastewater treatment. ” Environ. Sci. Technol, 48(2377) : .
[40] Lacasa E.,Tsolaki Z.,Sbokou M. A.,Rodrigo D.,Mantzavinos D. .2013 .Electrochemical disinfection of simulated ballast water on conductive diamond electrodes,” Chem. , 223(516) : .
[41] M. Rajab C.,Heim T.,Letzel J. E.,Drewes B.,Helmreich B. .2015 .Electrochemical disinfection using boron-doped diamond electrode - The synergetic effects of in situ ozone and free chlorine generation. , 121(47) : .
[42] .2014 .Effects of anodic potential and chloride ion on overall reactivity in electrochemical reactors designed for solar-powered wastewater treatment. ” Environ. Sci. Technol, 48(2377) : .
[43] J. Gomes A.,Matos M.,Gmurek M.,R. M. QuintaFerreira M. .2019 .Ozone and photocatalytic processes for pathogens removal from water: A review,”. Catalysts, 9(46) : .
[44] C. F. Green P. V.,Scarpino P.,Jensen N. J.,Jensen S. G.,Gibbs S. G.,Microbiol Can. J. .2004 .Disinfection of selected Aspergillus spp. using ultraviolet germicidal irradiation,”. , 50(221) : .
[45] J. Gomes D.,Frasson R. M.,Quinta-Ferreira A.,Matos A. .2019 .Removal of enteric pathogens from real wastewater using single and catalytic ozonation. , 11(127) : .
[46] K. A. Hamilton ,Environ .2018 .Cryptosporidium and Giardia in wastewater and surface water environments. , 47(1006) : .
[47] W. A. M. Hijnen E. F.,Beerendonk G. J.,Medema G. J. .2006 .Inactivation credit of UV radiation for viruses, bacteria and protozoan (oo)cysts in water: A review,” Water Res. , 40(3) : .
[48] .2001 .Genome of the extremely radiation-resistant bacterium Deinococcus radiodurans viewed from the perspective of comparative genomics,” Microbiol. Mol. Biol, 65(44) : .
[49] D T.,Koutchma L. J.,Forney C. I. Moraru .2019 .. Ultraviolet Light in Food Technology: Principles and Applications, 1 : .
[50] Rodriguez R. A.,Bounty S.,Beck S.,Chan C.,C. C. .2014 .Photoreactivation of bacteriophages after UV disinfection: Role of genome structure and impacts of UV source,” Water Res. , 55(143) : .
[51] Calgua B. .2014 .UVC inactivation of dsDNA and ssRNA viruses in water: UV fluences and a qPCRbased approach to evaluate decay on viral infectivity,” Food Environ. , 6(260) : .
[52] A. Shin J.-K.,Lee J.-K. .2009 .Enhanced effectiveness of medium-pressure ultraviolet lamps on human adenovirus 2 and its possible mechanism,”. Water Sci. Technol, 60(851) : .
[53] M. Guo H.,Hu J. R.,Bolton M. G.,El-Din M. G. .2009 .Comparison of low- and medium-pressure ultraviolet lamps: Photoreactivation of Escherichia coli and total coliforms in secondary effluents of municipal wastewater treatment plants,” Water Res. , 43(815) : .
[54] C. Guo ,“H ,Hazard J. .2017 .O₂ and/or TiO₂ photocatalysis under UV irradiation for the removal of antibiotic resistant bacteria and their antibiotic resistance genes,”. , 323(710) : .
[55] M. Guo H.,Hu J. R.,Bolton M. G.,El-Din M. G. .2009 .Comparison of low- and medium-pressure ultraviolet lamps: Photoreactivation of Escherichia coli and total coliforms in secondary effluents of municipal wastewater treatment plants,” Water Res. , 43(815) : .
[56] J. Chen S.,Loeb S.,-H. Kim S. .2017 .LED revolution: Fundamentals and prospects for UV disinfection applications. ” Environ. Sci. Water Res. Technol., 3(188) : .
[57] K. A. Sholtes K.,Lowe G. W.,Walters M. D.,Sobsey K. G.,Linden L. M.,Casanova L. M. .2016 .Comparison of ultraviolet light-emitting diodes and low-pressure mercury-arc lamps for disinfection of water,” Environ. , 37(2183) : .
[58] Hazard J. .2017 .O₂ and/or TiO₂ photocatalysis under UV irradiation for the removal of antibiotic resistant bacteria and their antibiotic resistance genes,”. , 323(710) : .
[59] K. A. Sholtes K.,Lowe G. W.,Walters M. D.,Sobsey K. G.,Linden L. M.,Casanova L. M. .2016 .Comparison of ultraviolet light-emitting diodes and low-pressure mercury-arc lamps for disinfection of water,” Environ. , 37(2183) : .
[60] Wang C.,Wang G.,Chem G. .2020 .Photocatalytic advanced oxidation processes for water treatment: Recent advances. , 15(3239) : .
[61] C. Regmi B.,Joshi S. K.,Ray R. P.,Pandey R. P. .2018 .Understanding mechanism of photocatalytic microbial decontamination of environmental wastewater,” Front. , 6(33) : .
[62] Luo Y.,Zhang C.,Zheng B.,Geng X.,Debliquy M.,Hydrog Int. J. .2017 .Hydrogen sensors based on noble metal doped metal-oxide semiconductor: A review,”. , 42(20386) : .
[63] Chen Y. .2021 .Advanced oxidation processes for water disinfection: Features, mechanisms. , 409(128207) : .
[64] Haq M.,Saeed S. G.,Khan M.,Ibrahim M. .2021 .Photocatalytic Applications of Titanium Dioxide (TiO₂). IntechOpen, : .
[65] D. .2021 .“Critical review of advanced oxidation processes in organic wastewater treatment. , 275(130104) : .
[66] .2013 .Photocatalytic activity of a nitrogendoped TiO₂ modified zeolite in the degradation of reactive yellow 125 azo dye. ” J. Taiwan Inst. Chem, 44(270) : .
[67] Ren Y.,Zeng D.,C₃N₄ D.,Catal Chin. J. .2019 .- based metal sulfide heterojunction photocatalysts for energy conversion: A review,”. , 40(289) : .
[68] .2015 .Recyclable non-enzymatic glucose sensor based on Ni. , 80(576) : .
[69] Md. M. R. Khan H. R.,Ong Z.,Yaakob Z. .2017 .Modified TiO₂ photocatalyst for CO₂ photocatalytic reduction: An overview. , 22(15) : .
[70] Roy N.,Sohn Y.,Pradhan D. .2013 .Synergy of lowenergy {101} and high-energy {001} TiO₂ crystal facets for enhanced photocatalysis. ” ACS Nano, 7(2532) : .
[71] Zhang Q.,Catal J. .2016 .The dependence of photocatalytic activity on the selective and nonselective deposition of noble metal cocatalysts on the facets of rutile TiO₂,”. , 337(36) : .
[72] Hou W.,Cronin S. B. .2013 .A review of surface plasmon resonance-enhanced photocatalysis,” Adv. , 23(1612) : .
[73] .2019 .Surface defect-controlled growth and high photocatalytic H₂ production efficiency of anatase TiO₂ nanosheets. ACS Appl. Mater. Interfaces, 11(37256) : .
[74] Li G.,Chen Q.,Lan J. .2014 .Facile synthesis, metastable phase induced morphological evolution and crystal ripening, and structure-dependent photocatalytic properties of 3D hierarchical anatase superstructures. ” ACS Appl. Mater. Interfaces, 6(22561) : .
[75] Apollo S.,Onyongo M. S.,Ochieng A.,Chem Iran. J. .2014 .zeolite hybrid system for treatment of molasses wastewater,”. , 33(107) : .
[76] Foster H. A.,Ditta I. B.,Varghese S. .2011 .Photocatalytic disinfection using titanium dioxide: Spectrum and mechanism of antimicrobial activity. ” Appl, 90 : .
[77] .2021 .Advanced oxidation processes for water disinfection: Features, mechanisms. , 409(128207) : .
[78] Ray S. K.,Dhakal D.,Pandey R. P.,Lee S. W. .2017 .photocatalyst for antibacterial application,” Mater. , 78(1164) : .
[79] .2017 .A Z-scheme magnetic recyclable Ag/AgBr@CoFe₂O₄ photocatalyst with enhanced photocatalytic performance for pollutant and bacterial elimination,” RSC Adv. , 7(30845) : .
[80] J. Gomes D.,Frasson R. M.,Quinta-Ferreira A.,Matos A. .2019 .Removal of enteric pathogens from real wastewater using single and catalytic ozonation. , 11(127) : .
[81] Padmavathy N.,Vijayaraghavan R.,Biomed J. .2011 .Interaction of ZnO nanoparticles with microbes-A physio and biochemical assay,”. , 7(813) : .
[82] Rtimi S.,Dionysiou D. D.,Pillai S. C.,Kiwi J. .2019 .Advances in catalytic/photocatalytic bacterial inactivation by nano Ag and Cu coated surfaces. ” Appl. Catal. B Environ, 240(291) : .
[83] P.-C. Maness S.,Smolinski D. M.,Blake Z.,Huang E. J.,Wolfrum W. A.,Jacoby W. A. .1999 .Bactericidal activity of photocatalytic TiO₂ reaction: Toward an understanding of its killing mechanism. ” Appl. Environ. Microbiol., 65(4094) : .
[84] K. P. Kühn .2003 .Disinfection of surfaces by photocatalytic oxidation with titanium dioxide and UVA light. , 53(71) : .
[85] Environ J. .2019 .Review on advances in photocatalytic water disinfection utilizing graphene and graphene derivatives-based nanocomposites,”. , 7(103132) : .
[86] .2021 .Advanced oxidation processes for water disinfection: Features, mechanisms. , 409(128207) : .
[87] .2019 .Inactivation of pathogenic microorganisms by sulfate radical: Present and future. , 371(222) : .
[88] Bosshard F.,Riedel K.,Schneider T.,Geiser C.,Bucheli M. .2010 .Protein oxidation and aggregation in UVA-irradiated Escherichia coli cells as signs of accelerated cellular senescence,” Environ. , 12(2931) : .
[89] Muller J. G.,Hickerson R. P.,Perez R. J.,Burrows C. J. .1997 .DNA damage from sulfite autoxidation catalyzed by a nickel(II) peptide. J. Am. Chem. Soc., 119(1501) : .
[90] J. D. Hoerter ,Photochem J. .2005 .Effects of sublethal UVA irradiation on activity levels of oxidative defense enzymes and protein oxidation in Escherichia coli,”. , 81(171) : .
[91] Wang W.,Li G.,Xia D.,An T.,Zhao H.,Wong and P. K. .2017 .Photocatalytic nanomaterials for solardriven bacterial inactivation: Recent progress. ” Environ. Sci. Nano, 4(782) : .
[92] Tomoda R.,Nakajima T.,Wake H. .1985 .Photoelectrochemical sterilization of microbial cells by semiconductor powders,” FEMS Microbiol. , 29(211) : .
[93] Laxma Reddy P. V.,Kavitha B.,Kumar Reddy P. A.,-H. Kim P. A. .2017 .-based photocatalytic disinfection of microbes in aqueous media: A review,” Environ. , 154(296) : .
[94] A C.,Pulgarin C. .2004 .Bactericidal action of illuminated TiO₂ on pure Escherichia coli and natural bacterial consortia: Post-irradiation events in the dark and assessment of the effective disinfection time. ” Appl. Catal. B Environ, 49(99) : .
[95] J. Bogdan J.,Zarzyńska J.,Pławińska-Czarnak J. .2015 .Comparison of infectious agents susceptibility to photocatalytic effects of nanosized titanium and zinc oxides: A practical approach,” Nanoscale Res. Lett., 10(309) : .
[96] .2018 .Biofiltration using C. fluminea for E. coli removal from water: Comparison with ozonation and photocatalytic oxidation. , 208(674) : .
[97] J. F. Gomes .2018 .Biofiltration using C. fluminea for E. coli removal from water: Comparison with ozonation and photocatalytic oxidation. , 208(674) : .
[98] A C.,Pulgarin C. .2005 .bacterial community present in wastewater,” Catal. , 101(331) : .
[99] Xiong P.,Hu J. .2013 .Inactivation/reactivation of antibiotic-resistant bacteria by a novel UVA/LED/TiO₂ system,” Water Res. , 47(4547) : .
[100] P. S. M. Dunlop M.,Ciavola L.,Rizzo D. A.,McDowell and J. A.,Byrne and J. A. .2015 .Effect of photocatalysis on the transfer of antibiotic resistance genes in urban wastewater,” Catal. , 240(55) : .
[101] A C.,Pulgarin C. .2004 .Bactericidal action of illuminated TiO₂ on pure Escherichia coli and natural bacterial consortia: Post-irradiation events in the dark and assessment of the effective disinfection time. ” Appl. Catal. B Environ, 49(99) : .
[102] Xiong P.,Hu J. .2013 .Inactivation/reactivation of antibiotic-resistant bacteria by a novel UVA/LED/TiO₂ system,” Water Res. , 47(4547) : .
[103] J. Bogdan J.,Zarzyńska J.,Pławińska-Czarnak J. .2015 .Comparison of infectious agents susceptibility to photocatalytic effects of nanosized titanium and zinc oxides: A practical approach,” Nanoscale Res. Lett., 10(309) : .
[104] P. S. M. Dunlop M.,Ciavola L.,Rizzo D. A.,McDowell and J. A.,Byrne and J. A. .2015 .Effect of photocatalysis on the transfer of antibiotic resistance genes in urban wastewater,” Catal. , 240(55) : .
[105] Biton Seror S.,Shamir D.,Albo Y.,Kornweitz H.,Burg A. .2022 .Elucidation of a mechanism for the heterogeneous electro-Fenton process and its application in the green treatment of azo dyes. , 286(131832) : .
[106] .2021 .Advanced oxidation processes for water disinfection: Features, mechanisms. , 409(128207) : .
[107] Wang N.,Zheng T.,Wang P.,Environ J. .2016 .A review on Fenton-like processes for organic wastewater treatment,”. , 4(762) : .
[108] Uhl A.,Gerstel M.,Chabalier S.,Dukan S.,Heliyon S. .2015 .Hydrogen peroxide induced cell death: One or two modes of action?,”. , 1(e00049) : .
[109] H. F. Diao X. Y.,Li J. D.,Gu H. C.,Shi Z. M.,Xie Z. M. .2004 .Electron microscopic investigation of the bactericidal action of electrochemical disinfection in comparison with chlorination, ozonation. , 39(1421) : .
[110] .2018 .Activation of peroxymonosulfate/persulfate by nanomaterials for sulfate radical-based advanced oxidation technologies. ” Curr. Opin. Chem, 19(51) : .
[111] Duan X.,Yang S.,Wacławek S.,Xiao R.,Dionysiou D. D.,Environ J. .2020 .Limitations and prospects of sulfate-radical based advanced oxidation processes,”. , 8(103849) : .
[112] .2020 .Electrochemically activated PMS and PDS: Radical oxidation versus nonradical oxidation,” Chem. , 391(123560) : .
[113] Giannakis S.,K.-Y. A. Lin F.,Ghanbari F.,Chem. Eng. J. F. .2021 .A review of the recent advances on the treatment of industrial wastewaters by Sulfate Radical-based Advanced Oxidation Processes (SR-AOPs),”. , 406(127083) : .
[114] .2020 .Iron-mediated activation of persulfate and peroxymonosulfate in both homogeneous and heterogeneous ways: A review,” Chem. , 384(123265) : .
[115] Abdelhaleem A.,Chu W. .2020 .Prediction of carbofuran degradation based on the hydroxyl radical's generation using the FeIII impregnated N doped-TiO₂/H₂O₂/visible LED photo-Fenton-like process,” Chem. , 382(122930) : .
[116] Mater Adv. Energy .2021 .Recent advance of transition-metal-based layered double hydroxide nanosheets: Synthesis, properties, modification, and electrocatalytic applications,”. , 11(2002863) : .
[117] O. JunSik D. E.,Salcedo C. A.,Medriano C. A.,Environ J. .2014 .Comparison of different disinfection processes in the effective removal of antibioticresistant bacteria and genes,”. , 26(1238) : .
[118] Moreira N. F. F. .2016 .Photocatalytic ozonation of urban wastewater and surface water using immobilized TiO₂ with LEDs: Micropollutants, antibiotic resistance genes and estrogenic activity,” Water Res. , 94(10) : .
[119] Mosteo R.,Lopez A. Varon,Muzard D.,Benitez N.,Giannakis S.,Pulgarin C. .2020 .Visible light plays a significant role during bacterial inactivation by the photo-Fenton process, even at sub-critical light intensities,” Water Res. , 174(115636) : .
[120] .2020 .Unfolding the action mode of light and homogeneous vs. heterogeneous photoFenton in bacteria disinfection and concurrent elimination of micropollutants in urban wastewater, mediated by iron oxides in Raceway Pond Reactors. ” Appl. Catal. B Environ, 263(118158) : .
[121] Amaral L. O.,Daniel- A. L. .2022 .MoS₂ and MoS₂ nanocomposites for adsorption and photodegradation of water pollutants: A review. , 27(6782) : .
[122] X. Wu ,-J. Zhu .2019 .Sono-Fenton hybrid process on the inactivation of Microcystis aeruginosa: Extracellular and intracellular oxidation,” Ultrason. , 53(68) : .
[123] J. Li ,Environ J. .2022 .Effective inactivation of Escherichia coli in aqueous solution by activated carbon-supported α- FeOOH as heterogeneous Fenton catalyst with high stability and reusability,”. , 10(107347) : .
[124] M. Tong F.,Liu Q.,Dong Z.,Ma Z.,Hazard J. .2020 .-deposited flower-like MoS₂ nanocomposites for the Fenton-like Escherichia coli disinfection and diclofenac degradation,”. , 385(121604) : .
[125] Zhou X. .2022 .Bacteria inactivation by sulfate radical: Progress and non-negligible disinfection byproducts. ” Front. Environ. Sci. Eng, 17(29) : .
[126] .2018 .Persulfate-mediated catalytic and photocatalytic bacterial inactivation by magnetic natural ilmenite. ” Appl. Catal. B Environ, 238(70) : .
[127] Braz V. S.,Melchior K.,Moreira C. G.,Front. Cell. Infect. Microbiol. C. G. .2020 .Escherichia coli as a multifaceted pathogenic and versatile bacterium,”. , 10(548492) : .
[128] Chem .2019 .A novel three-dimensional galvanic cell enhanced Fe²⁺/persulfate system: High efficiency, mechanism and damaging effect of antibiotic resistant E. coli and genes. , 362(667) : .
[129] .2017 .Activation of persulfates by natural magnetic pyrrhotite for water disinfection: Efficiency, mechanisms. , 112(236) : .
[130] Jung Y. J.,Oh B. S.,Kang and J.-W. .2008 .Synergistic effect of sequential or combined use of ozone and UV radiation for the disinfection of Bacillus subtilis spores,” Water Res. , 42(1613) : .
[131] J. Fang C.,Shang M.,Zeng M.,Ni M. .2014 .coli and bacteriophage MS2 disinfection by UV, ozone and the combined UV and ozone processes. ” Front. Environ. Sci. Eng, 8(547) : .
[132] Jung Y. J.,Oh B. S.,Kang and J.-W. .2008 .Synergistic effect of sequential or combined use of ozone and UV radiation for the disinfection of Bacillus subtilis spores,” Water Res. , 42(1613) : .
[133] J. Fang C.,Shang M.,Zeng M.,Ni M. .2014 .coli and bacteriophage MS2 disinfection by UV, ozone and the combined UV and ozone processes. ” Front. Environ. Sci. Eng, 8(547) : .
[134] A. C. Mecha M. S.,Onyango A.,Ochieng C. J. S.,Fourie M. N. B.,Momba M. N. B.,Catal J. .2016 .Synergistic effect of UV-vis and solar photocatalytic ozonation on the degradation of phenol in municipal wastewater: A comparative study,”. , 341(116) : .
[135] A. C. Mecha M. S.,Onyango A.,Ochieng M. N. B.,Momba M. N. B.,Environ Sci. Total .2017 .Evaluation of synergy and bacterial regrowth in photocatalytic ozonation disinfection of municipal wastewater,”. , (626) : 601-602.
[136] Moreira N. F. F. .2018 .“Solar treatment (H₂O₂, TiO₂- P25 and GO-TiO₂ photocatalysis, photo-Fenton) of organic micropollutants, human pathogen indicators, antibiotic resistant bacteria and related genes in urban wastewater,” Water Res. , 135(195) : .
[137] Hazard J. .2017 .O₂ and/or TiO₂ photocatalysis under UV irradiation for the removal of antibiotic resistant bacteria and their antibiotic resistance genes,”. , 323(710) : .
[138] Hazard J. .2017 .O₂ and/or TiO₂ photocatalysis under UV irradiation for the removal of antibiotic resistant bacteria and their antibiotic resistance genes,”. , 323(710) : .
[139] Deemter D.,I. Oller D.,Amat A. M.,Malato S.,Environ Sci. Total .2021 .Effect of salinity on preconcentration of contaminants of emerging concern by nanofiltration: Application of solar photo-Fenton as a tertiary treatment,”. , 756(143593) : .
[140] Rahim Pouran S.,Aziz A. R. Abdul,Wan W. M. A.,Daud W. M. A.,Ind J. .2015 .Review on the main advances in photoFenton oxidation system for recalcitrant wastewaters,”. , 21(53) : .
[141] .2021 .Critical review of advanced oxidation processes in organic wastewater treatment. , 275(130104) : .
[142] García-Fernández M. I.,Polo-López I. Oller,Fernández-Ibáñez P. .2012 .“Bacteria and fungi inactivation using Fe³⁺/sunlight, H₂O₂/sunlight and near neutral photo-Fenton: A comparative study. ” Appl. Catal. B Environ, (20) : 121-122.
[143] Aryee A. A.,Clean J. .2021 .A review on functionalized adsorbents based on peanut husk for the sequestration of pollutants in wastewater: Modification methods and adsorption study,”. , 310(127502) : .
[144] B. M. Souza A. C.,Cerqueira G. L.,Sant'Anna M.,Dezotti M. .2011 .Oil-refinery wastewater treatment aiming reuse by advanced oxidation processes (AOPs) combined with biological activated carbon (BAC),”. Ozone Sci. Eng, 33(403) : .
[145] Korkuna O.,Leboda R.,Skubiszewska-Zięba J.,T. J.,Ryczkowski J. .2006 .Structural and physicochemical properties of natural zeolites: Clinoptilolite and mordenite,” Microporous Mesoporous Mater. , 87(243) : .
[146] Alonso-Vicario .2010 .“Purification and upgrading of biogas by pressure swing adsorption on synthetic and natural zeolites,” Microporous Mesoporous Mater. , 134(100) : .
[147] Soon A. N.,Hameed B. H. .2011 .Heterogeneous catalytic treatment of synthetic dyes in aqueous media using Fenton and photo-assisted Fenton process. , 269(1) : .
[148] Buthiyappan A.,Aziz A. R. A.,Daud W. M. A. W. .2016 .Recent advances and prospects of catalytic advanced oxidation process in treating textile effluents. ” Rev. Chem, 32(1) : .
[149] Castañeda-Juárez ,Photochem J. .2019 .“Synthesis of TiO₂ catalysts doped with Cu, Fe, and Fe/Cu supported on clinoptilolite zeolite by an electrochemical-thermal method for the degradation of diclofenac by heterogeneous photocatalysis,”. , 380(111834) : .
[150] .2021 .-zeolite metal composites for photocatalytic degradation of organic pollutants in water. , 11(1367) : .
[151] Muleja A.,Tshangana C.,Gorimbo J.,I. Kamika J.,Mamba B. .2022 .The inactivation of Escherichia coli using cobalt-modified natural zeolite from a South African mine. ” Int. J. Environ. Sci. Technol, 19(9377) : .