This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Statistical Yearbook of the Republic of Poland 2014, Central Statistical Office, Warsaw, 2014.Statistical Yearbook of the Republic of Poland 2014, Central Statistical Office, Warsaw, 2014.Search in Google Scholar
http://encyklopedia.pwn.pl/haslo/azotany-V;3872892.htmlhttp://encyklopedia.pwn.pl/haslo/azotany-V;3872892.html,Search in Google Scholar
Fanning, J. (2000). The chemical reduction of nitrate in aqueous solution. Coordination Chemistry Reviews, 199(1), 159–179.FanningJ. (2000). The chemical reduction of nitrate in aqueous solution. Coordination Chemistry Reviews,199(1), 159–179.10.1016/S0010-8545(99)00143-5Search in Google Scholar
Reyter, D., Bélanger, D., & Roué, L. (2010). Nitrate removal by a paired electrolysis on copper and Ti/IrO2 coupled electrodes – Influence of the anode/cathode surface area ratio. Water Research, 44(6), 1918–1926.ReyterD.BélangerD., & RouéL. (2010). Nitrate removal by a paired electrolysis on copper and Ti/IrO2 coupled electrodes – Influence of the anode/cathode surface area ratio. Water Research, 44(6), 1918–1926.10.1016/j.watres.2009.11.037Search in Google Scholar
Fan, X., Guan, X., Ma, J., & Ai, H. (2009). Kinetics and corrosion products of aqueous nitrate reduction by iron powder without reaction conditions control. Journal of Environmental Sciences, 21(8), 1028–1035.FanX.GuanX.MaJ., & AiH. (2009). Kinetics and corrosion products of aqueous nitrate reduction by iron powder without reaction conditions control. Journal of Environmental Sciences, 21(8), 1028–1035.10.1016/S1001-0742(08)62378-5Search in Google Scholar
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4698595/https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4698595/,Search in Google Scholar
Nitrates and Nitrites; TEACH Chemical Summary. (2006) U.S. EPA, Toxicity and Exposure Assessment for Children’s Health.Nitrates and Nitrites; TEACH Chemical Summary. (2006) U.S. EPA, Toxicity and Exposure Assessment for Children’s Health.Search in Google Scholar
Fernández-Nava, Y., Marañón, E., Soons, J., & Castrillón, L. (2010). Denitrification of high nitrate concentration wastewater using alternative carbon sources. Journal of Hazardous Materials, 173(1–3), 682–688.Fernández-NavaY.MarañónE.SoonsJ., & CastrillónL. (2010). Denitrification of high nitrate concentration wastewater using alternative carbon sources. Journal of Hazardous Materials, 173(1–3), 682–688.10.1016/j.jhazmat.2009.08.140Search in Google Scholar
Perygy, A., & Spitsov, D. (2011). Application of membrane techniques for municipal wastewater treatment and reuse. Inżynieria Ekologiczna, 24, 107–119.PerygyA., & SpitsovD. (2011). Application of membrane techniques for municipal wastewater treatment and reuse. Inżynieria Ekologiczna, 24, 107–119.Search in Google Scholar
Dziubek, A., & Mackiewicz, J. (2009). Removal of nitrates from water by selective ion exchange. Environment Protection Engineering, 35(1), 171–177.DziubekA., & MackiewiczJ. (2009). Removal of nitrates from water by selective ion exchange. Environment Protection Engineering, 35(1), 171–177.Search in Google Scholar
Dziewiński, J., & Marczak, S. (2002). Electrochemical reduction of nitrate in the presence of an amide. United States Patent No.: US 6,436,275 B1.DziewińskiJ., & MarczakS. (2002). Electrochemical reduction of nitrate in the presence of an amide. United States Patent No.: US 6,436,275 B1.Search in Google Scholar
Li, M., Feng, C., Zhang, Z., Shen, Z., & Sugiura, N. (2009). Electrochemical reduction of nitrate using various anodes and a Cu/Zn cathode. Electrochemistry Communications, 11(10), 1853–1856.LiM.FengC.ZhangZ.ShenZ., & SugiuraN. (2009). Electrochemical reduction of nitrate using various anodes and a Cu/Zn cathode. Electrochemistry Communications, 11(10), 1853–1856.10.1016/j.elecom.2009.08.001Search in Google Scholar
Wenliang, G., Naijia, G., & Jixin Titania, C. (2003). Supported Pd-Cu bimetallic catalyst for the reduction of nitrate in drinking water. Applied Catalysis B: Environmental, 46, 341–351.WenliangG.NaijiaG., & Jixin TitaniaC. (2003). Supported Pd-Cu bimetallic catalyst for the reduction of nitrate in drinking water. Applied Catalysis B: Environmental, 46, 341–351.10.1016/S0926-3373(03)00226-1Search in Google Scholar
Zhang, J., Hao, Z., Zhang, Z., Yang, Y., & Xu, X. (2010). Kinetics of nitrate reductive denitrification by nanoscale zero-valent iron. Process Safety and Environmental Protection, 88(6), 439–445.ZhangJ.HaoZ.ZhangZ.YangY., & XuX. (2010). Kinetics of nitrate reductive denitrification by nanoscale zero-valent iron. Process Safety and Environmental Protection, 88(6), 439–445.10.1016/j.psep.2010.06.002Search in Google Scholar
Hosseini, S. M., Ataie-Ashtiani, B., & Kholghi, M. (2011). Nitrate reduction by nano-Fe/Cu particles in packed column. Desalination, 276(1–3), 214–221.HosseiniS. M.Ataie-AshtianiB., & KholghiM. (2011). Nitrate reduction by nano-Fe/Cu particles in packed column. Desalination, 276(1–3), 214–221.10.1016/j.desal.2011.03.051Search in Google Scholar
Barbusiński, K., & Żołnierczyk, M. (2016). Chemical Reduction Of Nitrates In The Wastewater From 2-EHN Production. Architecture, Civil Engineering, Environment, 9(4), 101–106.BarbusińskiK., & ŻołnierczykM. (2016). Chemical Reduction Of Nitrates In The Wastewater From 2-EHN Production. Architecture, Civil Engineering, Environment, 9(4), 101–106.10.21307/acee-2016-056Search in Google Scholar
Wiśniewski, J., Różańska, A. (2002). Usuwanie azotanów z roztworów wodnych metodą elektrodializy. Ochrona środowiska, 4, 11–15.WiśniewskiJ.RóżańskaA. (2002). Usuwanie azotanów z roztworów wodnych metodą elektrodializy. Ochrona środowiska, 4, 11–15.Search in Google Scholar
Sieroń, A., & Świderska-Bróż, A. (1998). Usuwanie azotanów z wody w procesie wymiany jonowej. Ochrona środowiska, 7(71), 7–9.SierońA., & Świderska-BróżA. (1998). Usuwanie azotanów z wody w procesie wymiany jonowej. Ochrona środowiska, 7(71), 7–9.Search in Google Scholar
Barrabes, N., Just, J., Dafinov, A., Medina, F., Fierro, J., Sueiras, J., Cesteros, Y. (2006). Catalytic reduction of nitrate on Pt-Cu and Pd-Cu on active carbon using continuous reactor. The effect of copper nanoparticles. Applied Catalysis B: Environmental, 62(1–2), 77–85.BarrabesN.JustJ.DafinovA.MedinaF.FierroJ.SueirasJ.CesterosY. (2006). Catalytic reduction of nitrate on Pt-Cu and Pd-Cu on active carbon using continuous reactor. The effect of copper nanoparticles. Applied Catalysis B: Environmental, 62(1–2), 77–85.Search in Google Scholar
Ottley, C. J., Davison, W., & Edmunds, W. M. (1997). Chemical catalysis of nitrate reduction by iron(II). Geochemica Et Cosmochimica Acta, 61(9), 1819–1828.OttleyC. J.DavisonW., & EdmundsW. M. (1997). Chemical catalysis of nitrate reduction by iron(II). Geochemica Et Cosmochimica Acta, 61(9), 1819–1828.10.1016/S0016-7037(97)00058-6Search in Google Scholar
Liou, Y., Lo, S., Lin, C., Kuan, W., & Weng, S. (2005). Chemical reduction of an unbuffered nitrate solution using catalyzed and uncatalyzed nanoscale iron particles. Journal of Hazardous Materials, 127(1–3), 102–110.LiouY.LoS.LinC.KuanW., & WengS. (2005). Chemical reduction of an unbuffered nitrate solution using catalyzed and uncatalyzed nanoscale iron particles. Journal of Hazardous Materials, 127(1–3), 102–110.10.1016/j.jhazmat.2005.06.029Search in Google Scholar
Glass, C., & Silverstein, J. (1999). Denitrification of high-nitrate, high-salinity wastewater. Water Research, 33(1), 223–229.GlassC., & SilversteinJ. (1999). Denitrification of high-nitrate, high-salinity wastewater. Water Research, 33(1), 223–229.10.1016/S0043-1354(98)00177-8Search in Google Scholar
Chen, Y., Li, C., & Chen, S. (2005). Fluidized zero valent iron bed reactor for nitrate removal. Chemosphere, 59(6), 753–759.ChenY.LiC., & ChenS. (2005). Fluidized zero valent iron bed reactor for nitrate removal. Chemosphere, 59(6), 753–759.10.1016/j.chemosphere.2004.11.020Search in Google Scholar
Garcia-Segura, S., Lanzarini-Lopes, M., Hristovski, K., & Westerhoff, P. (2018). Electrocatalytic reduction of nitrate: Fundamentals to full-scale water treatment applications. Applied Catalysis B: Environmental, 236, 546–568.Garcia-SeguraS.Lanzarini-LopesM.HristovskiK., & WesterhoffP. (2018). Electrocatalytic reduction of nitrate: Fundamentals to full-scale water treatment applications. Applied Catalysis B: Environmental, 236, 546–568.10.1016/j.apcatb.2018.05.041Search in Google Scholar
