This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Barbusiński, K., Nocoń, W., Nocoń, K., & Kernert, J. (2012). The role of suspended solids in the transport of heavy metals in surface water, exemplified by the Klodnica River (Upper Silesia). Ochrona Srodowiska, 34(2), 33–38.BarbusińskiK.NocońW.NocońK.KernertJ.2012The role of suspended solids in the transport of heavy metals in surface water, exemplified by the Klodnica River (Upper Silesia)3423338Search in Google Scholar
https://www.scbt.com/scbt/product/potassium-ferrate-vi-39469-86-8 [01.02.2018].Search in Google Scholar
Tiwari, D., & Lee, S.M. (2011). Ferrate (VI) in the treatment of wastewaters: a new generation green chemical. Waste Water Treatment and Reutilization, 12, 241–276.TiwariD.LeeS.M.2011Ferrate (VI) in the treatment of wastewaters: a new generation green chemical1224127610.5772/15500Search in Google Scholar
Sharma, V.K., Kazama, F., Jiangyong, H., & Ray, A.K. (2005). Ferrates iron(VI) and iron(V), Environmentally friendly oxidants and disinfectants. Journal of Water and Health, 3(1), 45–58.SharmaV.K.KazamaF.JiangyongH.RayA.K.2005Ferrates iron(VI) and iron(V), Environmentally friendly oxidants and disinfectants31455810.2166/wh.2005.0005Search in Google Scholar
Wei, Y.L., Wang, Y.S., & Liu, C.H. (2015). Preparation of potassium ferrate from spent steel pickling liquid. Metals, 5(4), 1770–1787.WeiY.L.WangY.S.LiuC.H.2015Preparation of potassium ferrate from spent steel pickling liquid541770178710.3390/met5041770Search in Google Scholar
Sharma, V.K. (2002). Potassium ferrate(VI): an environmental friendly oxidant. Advances in Environmental Research, 6(2), 143–156.SharmaV.K.2002Potassium ferrate(VI): an environmental friendly oxidant6214315610.1016/S1093-0191(01)00119-8Search in Google Scholar
Li, C., Li, X.Z., & Graham, N. (2005). A study of preparation and reactivity of potassium ferrate. Chemosphere, 61(4), 537–543.LiC.LiX.Z.GrahamN.2005A study of preparation and reactivity of potassium ferrate61453754310.1016/j.chemosphere.2005.02.027Search in Google Scholar
Kooti, M., Jorfi, M., & Javadi, H. (2010). Rapid chemical synthesis of four ferrate (VI) compounds. Journal of the Iranian Chemical Society, 7(4), 814–819.KootiM.JorfiM.JavadiH.2010Rapid chemical synthesis of four ferrate (VI) compounds7481481910.1007/BF03246073Search in Google Scholar
Li, C. (2006). Mechanism and performance of potassium ferrate in endocrine disrupting chemicals. Dept. Of Civil & Structural Engineering, 1–250.LiC.2006Mechanism and performance of potassium ferrate in endocrine disrupting chemicals1250Search in Google Scholar
Liu, Z., Kanjo, Y., & Mizutani, S. (2009). Removal mechanism for endocrine disrupting compounds (EDC’s) in wastewater treatment – physical means, biodegradation and chemical advanced oxidation: a review. Science of the Total Environment, 407(2), 731–748.LiuZ.KanjoY.MizutaniS.2009Removal mechanism for endocrine disrupting compounds (EDC’s) in wastewater treatment – physical means, biodegradation and chemical advanced oxidation: a review407273174810.1016/j.scitotenv.2008.08.039Search in Google Scholar
Colbrom, T., vom Saal, F.S., & Soto, A.M. (1993). Developmental effects of endocrine disrupting chemicals in wildlife and humans. Environmental Health Perspectives, 101(5), 378–384.ColbromT.vom SaalF.S.SotoA.M.1993Developmental effects of endocrine disrupting chemicals in wildlife and humans101537838410.1289/ehp.93101378Search in Google Scholar
Jiang, J.Q., Yin, Q., Zhou, J.L., & Pearce, P. (2005). Occurrence and treatment trials of endocrine disrupting chemicals (EDC’s) in wastewaters. Chemosphere, 61(4), 544–550.JiangJ.Q.YinQ.ZhouJ.L.PearceP.2005Occurrence and treatment trials of endocrine disrupting chemicals (EDC’s) in wastewaters61454455010.1016/j.chemosphere.2005.02.029Search in Google Scholar
Lee, Y., & Yoon, J. (2005). Oxidation of phenolic contaminants during water treatment with ferrate (Fe(VI)): a kinetic study. Applied Chemistry, 9(1), 205–208.LeeY.YoonJ.2005Oxidation of phenolic contaminants during water treatment with ferrate (Fe(VI)): a kinetic study91205208Search in Google Scholar
Li, C. Mechanisms and performance of potassium ferrate in endocrine disrupting chemicals. PhD Thesis. Department of Civil and Structural Engineering. The Hong Kong Polytechnic University, 05.2006. https://www.researchgate.net/publication/47870596_Mechanisms_and_performance_of_potassium_ferrate_in_endocrine_disrupting_chemicals [30.07.2019].LiC.Mechanisms and performance of potassium ferrate in endocrine disrupting chemicalsPhD ThesisDepartment of Civil and Structural Engineering. The Hong Kong Polytechnic University052006Search in Google Scholar
Han, Q., Dong, W., Wang, H., Liu, T., Tian, Y., & Song, X. (2018). Degradation of tetrabromobisphenol A by ferrate(VI) oxidation: performance, inorganic and organic products, pathway and toxicity control. Chemosphere, 198, 92–102.HanQ.DongW.WangH.LiuT.TianY.SongX.2018Degradation of tetrabromobisphenol A by ferrate(VI) oxidation: performance, inorganic and organic products, pathway and toxicity control1989210210.1016/j.chemosphere.2018.01.117Search in Google Scholar
Yang, B., Ying, G., Zhao, J., Zhou, L., & Chen, F. (2012). Removal of selected endocrine disrupting chemicals (EDC’s) and pharmaceuticals and personal care products (PPCP’s) during ferrate(VI) treatment of secondary wastewater effluents. Water Research, 46(7), 2194–2204.YangB.YingG.ZhaoJ.ZhouL.ChenF.2012Removal of selected endocrine disrupting chemicals (EDC’s) and pharmaceuticals and personal care products (PPCP’s) during ferrate(VI) treatment of secondary wastewater effluents4672194220410.1016/j.watres.2012.01.047Search in Google Scholar
Lee, Y., Yoon, J., & von Gunten, U. (2005). Kinetics of the oxidation of phenols and phenolic endocrine disruptors during water treatment with ferrate (Fe(VI)). Environmental Science Technology, 39(22), 8978–8984.LeeY.YoonJ.von GuntenU.2005Kinetics of the oxidation of phenols and phenolic endocrine disruptors during water treatment with ferrate (Fe(VI))39228978898410.1021/es051198wSearch in Google Scholar
Wang, G., & Feng, L. (2013). Experimental studies on application of potassium ferrate for 3-methylphenol removal from solution in laboratory. Procedia Environmental Sciences, 18, 486–492.WangG.FengL.2013Experimental studies on application of potassium ferrate for 3-methylphenol removal from solution in laboratory1848649210.1016/j.proenv.2013.04.065Search in Google Scholar
Li, C., & Dong, F. (2016). Ferrites and Ferrates: Chemistry and Applications in Sustainable Energy and Environment. American Chemical Society.LiC.DongF.2016American Chemical SocietySearch in Google Scholar
Li, C., Li, X.Z., Graham, A.N.N., & Gao, N. (2008). The aqueous degradation of Bisphenol A and steroid estrogens by ferrate. Water Research, 42(1–2), 109–120.LiC.LiX.Z.GrahamA.N.N.GaoN.2008The aqueous degradation of Bisphenol A and steroid estrogens by ferrate421–210912010.1016/j.watres.2007.07.023Search in Google Scholar
Peings, V., Frayret, J., & Pigot, T. (2015). Mechanism for the oxidation of phenol by sulfatoferrate (VI): Comparison with various oxidants. Journal of Environmental Management, 1, 287–296.PeingsV.FrayretJ.PigotT.2015Mechanism for the oxidation of phenol by sulfatoferrate (VI): Comparison with various oxidants128729610.1016/j.jenvman.2015.04.004Search in Google Scholar
Anquandah, G.A.K., & Sharma, V.K. (2009). Oxidation of octylphenol by ferrate(VI). Journal of Environmental Science and Health, Part A, 44(1), 62–66.AnquandahG.A.K.SharmaV.K.2009Oxidation of octylphenol by ferrate(VI)441626610.1080/10934520802515368Search in Google Scholar
Lee, S.M., & Tiwari, D. (2009). Application of ferrate(VI) in treatment of industrial wastes containing metal-complexed cyanides: a green treatment. Journal of Environmental Science, 21(10), 1347–1352.LeeS.M.TiwariD.2009Application of ferrate(VI) in treatment of industrial wastes containing metal-complexed cyanides: a green treatment21101347135210.1016/S1001-0742(08)62425-0Search in Google Scholar
Lee, Y., & von Gunten, U. (2010). Oxidative transformation of micropollutants during municipal waste-water treatment: comparison of kinetic aspects of selective (chlorine, chlorine dioxide, ferrate(VI) and ozone) and non-selective oxidants (hydroxyl radical). Water Resources, 44(2), 555–566.LeeY.von GuntenU.2010Oxidative transformation of micropollutants during municipal waste-water treatment: comparison of kinetic aspects of selective (chlorine, chlorine dioxide, ferrate(VI) and ozone) and non-selective oxidants (hydroxyl radical)442555566Search in Google Scholar
Yang, B., Ying, G.G., Chen, Z.F., Zhao, J.L, Peng, F.Q., & Chen, X.W. (2014). Ferrate(VI) oxidation of tetrabromobisphenol A in comparison with bisphenol A. Water Research, 62, 211–219.YangB.YingG.G.ChenZ.F.ZhaoJ.LPengF.Q.ChenX.W.2014Ferrate(VI) oxidation of tetrabromobisphenol A in comparison with bisphenol A6221121910.1016/j.watres.2014.05.056Search in Google Scholar
Prochaska, K., Bielska, M., & Dopierała, K. (2009). Selected physicochemical aspects of membrane filtration. Membrany Teoria i Praktyka, III, 80–109.ProchaskaK.BielskaM.DopierałaK.2009Selected physicochemical aspects of membrane filtrationIII80109Search in Google Scholar
Janeczek, M., Jakubiec, J., & Mizerski, A. (2015). Evaluation of the wetting and extinguishing abilities of anionic and nonionic surfactants in conditions similar to practical by using methods based on NFPA 18 standard. Przemysł Chemiczny, 94(10), 1737–1741.JaneczekM.JakubiecJ.MizerskiA.2015Evaluation of the wetting and extinguishing abilities of anionic and nonionic surfactants in conditions similar to practical by using methods based on NFPA 18 standard941017371741Search in Google Scholar
Eng, Y.Y., Sharma, V.K., & Ray, A.K. (2006). Ferrate (VI): green chemistry oxidant for degradation of cationic surfactant. Chemosphere, 63(10), 1785–1790.EngY.Y.SharmaV.K.RayA.K.2006Ferrate (VI): green chemistry oxidant for degradation of cationic surfactant63101785179010.1016/j.chemosphere.2005.08.062Search in Google Scholar
Ebele, A.J., Abou-Elwafa, A., & Stuart, M.H. (2017). Pharmaceuticals and personal care products (PPCPs) in the freshwater aquatic environment. Journal of Emerging Contaminants, 3(1), 1–16.EbeleA.J.Abou-ElwafaA.StuartM.H.2017Pharmaceuticals and personal care products (PPCPs) in the freshwater aquatic environment3111610.1016/j.emcon.2016.12.004Search in Google Scholar
Jiang, J.Q. (2013). The role of ferrate(VI) in the remediation of emerging micro pollutants. Procedia Environmental Science, 18, 418-426.JiangJ.Q.2013The role of ferrate(VI) in the remediation of emerging micro pollutants1841842610.1016/j.proenv.2013.04.056Search in Google Scholar
Noorhasan, N., Patel, B., & Sharma, V.K. (2010). Ferrate(VI) oxidation of glycine and glycyloglycine: kinetics and products. Water Research, 44(3), 927–935.NoorhasanN.PatelB.SharmaV.K.2010Ferrate(VI) oxidation of glycine and glycyloglycine: kinetics and products44392793510.1016/j.watres.2009.10.003Search in Google Scholar
Diaz-Cruz, M.S., & Barcelo, D. (2015). Personal Care Products in the Aquatic Environment, Springer International Publishing.Diaz-CruzM.S.BarceloD.2015Springer International Publishing10.1007/978-3-319-18809-6Search in Google Scholar
Wu, K., Wang, H., Zhou, C., Amina, Y., & Si, Y. (2018). Efficient oxidative removal of sulfonamide antibiotics from the wastewater by potassium ferrate. Journal of Advanced Oxidation Technologies, 21(1), 97–108.WuK.WangH.ZhouC.AminaY.SiY.2018Efficient oxidative removal of sulfonamide antibiotics from the wastewater by potassium ferrate2119710810.26802/jaots.2017.0053Search in Google Scholar
Zhou, Z., & Jiang, J.Q. (2015). Reaction kinetics and oxidation products formation in the degradation of ciprofloxacin and ibuprofen by ferrate(VI). Chemosphere, 119, 95–100.ZhouZ.JiangJ.Q.2015Reaction kinetics and oxidation products formation in the degradation of ciprofloxacin and ibuprofen by ferrate(VI)1199510010.1016/j.chemosphere.2014.04.006Search in Google Scholar
Karlesa, A., De Vera, G.A.D, Dodd, M.C., Park, J., Espino, M.P.B., & Lee, Y. (2014). Ferrate(VI) oxidation of β-lactam antibiotics: reaction, antibacterial activity changes, and transformation products. Environmental Science Technology, 48(17), 10380–10389.KarlesaA.De VeraG.A.DDoddM.C.ParkJ.EspinoM.P.B.LeeY.2014Ferrate(VI) oxidation of β-lactam antibiotics: reaction, antibacterial activity changes, and transformation products4817103801038910.1021/es5028426Search in Google Scholar
Anquandah, G., Ray, M.B., Ray, A.K., Al.-Abduly, A.J., & Sharma, V.K. (2011). Oxidation of X-ray compound ditrizoic acid by ferrate (VI). Environmental Technology, 32(3), 261–267.AnquandahG.RayM.B.RayA.K.Al.-AbdulyA.J.SharmaV.K.2011Oxidation of X-ray compound ditrizoic acid by ferrate (VI)32326126710.1080/09593330.2010.496467Search in Google Scholar
Anquandah, G.A.K., Sharma, V.K., Panditi, V.R., Gardinali, P.R., Kim, H., & Oturan, M.A. (2013). Ferrate(VI) oxidation of propranolol: kinetics and products. Chemosphere, 91(1), 105–109.AnquandahG.A.K.SharmaV.K.PanditiV.R.GardinaliP.R.KimH.OturanM.A.2013Ferrate(VI) oxidation of propranolol: kinetics and products91110510910.1016/j.chemosphere.2012.12.001Search in Google Scholar
Sharma, V.K., Zboril, R., & Varma, R.S. (2015). Ferrates: greener oxidants with multimodal action in water treatment technologies. Accounts of Chemical Research, 48(2), 182–191.SharmaV.K.ZborilR.VarmaR.S.2015Ferrates: greener oxidants with multimodal action in water treatment technologies48218219110.1021/ar5004219Search in Google Scholar
Huber, M.M., Canonica, S., Park, G., & von Gunten, U. (2003). Oxidation of pharmaceuticals during ozonation and advanced oxidation processes. Environmental Science and Technology, 37(5), 1016–1024.HuberM.M.CanonicaS.ParkG.von GuntenU.2003Oxidation of pharmaceuticals during ozonation and advanced oxidation processes3751016102410.1021/es025896hSearch in Google Scholar
Sharma, V.K., Mishra, S.M., & Ray, A.K. (2006). Kinetic assessment of the potassium ferrate(VI) oxidation of antibacterial drug sulfamethoxazole. Chemosphere, 62, 128–134.SharmaV.K.MishraS.M.RayA.K.2006Kinetic assessment of the potassium ferrate(VI) oxidation of antibacterial drug sulfamethoxazole6212813410.1016/j.chemosphere.2005.03.095Search in Google Scholar
Sharma, V.K., Mishra, S.M., & Nesnas, N. (2006). Oxidation of sulfonamide antimicrobials by ferrate(VI). Environmental Science and Technology, 40(23), 7222–7227.SharmaV.K.MishraS.M.NesnasN.2006Oxidation of sulfonamide antimicrobials by ferrate(VI)40237222722710.1021/es060351zSearch in Google Scholar
Zhao, J., Liu Y., Wang, Q., Fu, Y., Lu, X., & Bai, X. (2018). The self-catalysis of ferrate(VI) by its reactive byproducts or reductive substances for the degradation of diclofenac: kinetics, mechanism and transformation products. Separation and Purification Technology, 192, 412–418.ZhaoJ.LiuY.WangQ.FuY.LuX.BaiX.2018The self-catalysis of ferrate(VI) by its reactive byproducts or reductive substances for the degradation of diclofenac: kinetics, mechanism and transformation products19241241810.1016/j.seppur.2017.10.030Search in Google Scholar
Rodriguez-Mozaz, S., Chamorro, S., Marti, E., & Huerta, B. (2015). Occurrence of antibiotics and antibiotic resistance genes in hospital and urban wastewaters and their impact on the receiving river. Water Resources, 69, 234–242.Rodriguez-MozazS.ChamorroS.MartiE.HuertaB.2015Occurrence of antibiotics and antibiotic resistance genes in hospital and urban wastewaters and their impact on the receiving river6923424210.1016/j.watres.2014.11.021Search in Google Scholar
Sharma, V.K., Johnson, N., Cizmas, L., McDonald, T.J., & Kim, H. (2016). A review of the influence of treatment strategies on antibiotic resistant bacteria and antibiotic resistance genes. Chemosphere, 150, 702–714.SharmaV.K.JohnsonN.CizmasL.McDonaldT.J.KimH.2016A review of the influence of treatment strategies on antibiotic resistant bacteria and antibiotic resistance genes15070271410.1016/j.chemosphere.2015.12.084Search in Google Scholar
Feng, M., & Wang, X. (2016). Degradation of fluoroquinolone antibiotics by ferrate(VI): effects of water constituents and oxidized products. Water Research, 103, 48–57.FengM.WangX.2016Degradation of fluoroquinolone antibiotics by ferrate(VI): effects of water constituents and oxidized products103485710.1016/j.watres.2016.07.014Search in Google Scholar
Thomas, M., Barbusiński, K., Kliś, S., Szpyrka, E., & Chyc, M. (2018). Synthetic textile wastewater treatment using potassium ferrate(VI) – application of Taguchi method for optimisation of experiment. Fibres Text. Estern Eur. 26(3), 111–117.ThomasM.BarbusińskiK.KliśS.SzpyrkaE.ChycM.2018Synthetic textile wastewater treatment using potassium ferrate(VI) – application of Taguchi method for optimisation of experiment26311111710.5604/01.3001.0011.7313Search in Google Scholar
Kliś, S., Barbusiński, K., Thomas, M., & Mochnacka, A. (2019). Application of potassium ferrate(VI) for oxidation of selected pollutants in aquatic environment – short review. Architecture Civil Engineering Environment. 12(1), 129–137.KliśS.BarbusińskiK.ThomasM.MochnackaA.2019Application of potassium ferrate(VI) for oxidation of selected pollutants in aquatic environment – short review12112913710.21307/acee-2019-012Search in Google Scholar
Thomas, M., Kliś, S., Barbusiński, K., & Chyc, M. (2019). Removal of Acid Red 27, Reactive Black 5 and Acid Green 16 from aqueous solutions using potassium ferrate(VI). Fibres Text. Estern Eur. 27(4), 71–75.ThomasM.KliśS.BarbusińskiK.ChycM.2019Removal of Acid Red 27, Reactive Black 5 and Acid Green 16 from aqueous solutions using potassium ferrate(VI)274717510.5604/01.3001.0013.1821Search in Google Scholar