References

  1. M.P. Chen, T.E. Graedel, A half-century of global phosphorus flows, stocks, production, consumption, recycling, and environmental impacts, Global Environ. Change, 36 (2016) 139–152.
  2. B. Cieślik, P. Konieczka, A review of phosphorus recovery methods at various steps of wastewater treatment and sewage sludge management. The concept of “no solid waste generation” and analytical methods, J. Cleaner Prod., 142 (2017) 1728–1740.
  3. D.W. Schindler, S.R. Carpenter, S.C. Chapra, R.E. Hecky, D.M. Orihel, Reducing phosphorus to Curb Lake eutrophication is a success, Environ. Sci. Technol., 50 (2016) 8923–8929.
  4. B.B. Qiu, F. Duan, Synthesis of industrial solid wastes/biochar composites and their use for adsorption of phosphate: from surface properties to sorption mechanism, Colloids Surf., A, 571 (2019) 86–93.
  5. F.Z. Xie, C.N. Da, F.J. Zhang, J. Zhang, X. Han, Y.J. Ge, G.L. Li, Phosphorus removal from eutrophic waters with a novel lanthanum-modified diatomite, Asian J. Chem., 25 (2013) 5759–5761.
  6. Ordinance Minister For Maritime Economy and Inland Navigation of July 12, 2019, On Substances that are Particularly Harmful to the Aquatic Environment and the Conditions to be Met When Entering Wastewater or Into the Ground, As Well as When Discharging Rainwater or Snowmelt to Waters or Water Facilities.
  7. D. Cordell, J.O. Drangert, S. White, The story of phosphorus: global food security and food for thought, Global Environ. Change, 19 (2009) 292–305.
  8. W.H. Schlesinger, E. Bernhardt, Biogeochemistry: An Analysis of Global Change, Academic Press, Waltham, MA, 2013.
  9. B.L. Sorensen, O.L. Dall, K. Habib, Environmental and resource implications of phosphorus recovery from waste activated sludge, J. Waste Manage., 45 (2015) 391–399.
  10. S. Gubernat, A. Masłoń, J. Czarnota, P. Koszelnik, Reactive materials in the removal of phosphorus compounds from wastewater—a review, Materials, 13 (2020) 3377, doi: 10.3390/ma13153377.
  11. H.J. Chen, W.Z. Zhou, S.N. Zhu, F. Liu, L. Qin, C. Xu, Z.M. Wang, Biological nitrogen and phosphorus removal by a phosphorus-accumulating bacteria Acinetobacter sp. strain C-13 with the ability of heterotrophic nitrification– aerobic denitrification, Bioresour. Technol., 322 (2021) 124507, doi:10.1016/j.biortech.2020.124507.
  12. H.K. Li, Y.M. Zhong, H. Huang, Z.X. Tan, Y. Sun, H. Liu, Simultaneous nitrogen and phosphorus removal by interactions between phosphate accumulating organisms (PAOs) and denitrifying phosphate accumulating organisms (DPAOs) in a sequencing batch reactor, Sci. Total Environ., 744 (2020) 140852, doi:10.1016/j.scitotenv.2020.140852.
  13. E.D. Roy, Phosphorus recovery and recycling with ecological engineering: a review, Ecol. Eng., 98 (2017) 213–227.
  14. E. Wiśniowska, W. Nocoń, K. Moraczewska-Majkut, Mikroplastik w ściekach i osadach ściekowych (Microplastic in sewage and sewage sludge), Gaz, Woda i Technika Sanitarna (Gas, Water and Sanitary Technology), 7 (2018) 269–275.
  15. X.Y. Ji, X. Liu, W.L. Yang, T. Xu, X. Wang, X.Q. Zhang, L.M. Wang, X.H. Mao, X. Wang, Sustainable phosphorus recovery from wastewater and fertilizer production in microbial electrolysis cells using the biochar-based cathode, Sci. Total Environ., 807 (2022) 150881, doi: 10.1016/j.scitotenv.2021.150881.
  16. C. Santiviago, J. Peralta, I. López, Phosphorus removal from wastewater through struvite crystallization in a continuous fluidized-bed reactor: an improved comprehensive model, Chem. Eng. J., 430 (2022) 132903, doi:10.1016/j.cej.2021.132903.
  17. V. Cucarella, T. Zaleski, R. Mazurek, Phosphorus sorption capacity of different types of opoka, J. Environ. Qual., 38 (2009) 381–392.
  18. D.Y. Wu, B.H. Zhang, C.J. Li, Z.J. Zhang, H.N. Kong, Simultaneous removal of ammonium and phosphate by zeolite synthesized from fly ash as influenced by salt treatment, J. Colloid Interface Sci., 304 (2006) 300–306.
  19. L. Johansson, L. Hylander, Phosphorus removal from wastewater by filter media: retention and estimated plant availability of sorbed phosphorus, J. Polish Acad. Sci., 48 (1998) 397–409.
  20. R.H. Li, J.J. Wang, B.Y. Zhou, M.K. Awasthi, A. Ali, Z.Q. Zhang, A.H. Lahori, A. Mahar, Recovery of phosphate from aqueous solution by magnesium oxide decorated magnetic biochar and its potential as phosphate-based fertilizer substitute, Bioresour. Technol., 215 (2016) 209–214.
  21. J.T. Bunce, E. Ndam, I.D. Ofiteru, A. Moore, D.W. Graham, A review of phosphorus removal technologies and their applicability to small-scale domestic wastewater treatment systems, Front. Environ. Sci., 6 (2018) 15, doi: 10.3389/ fenvs.2018.00008.
  22. A. Masłoń, J. Czarnota, Efficiency of brick dust and powdered ceramsite in the phosphorus removal from wastewater, J. Ecol. Eng., 21 (2020) 63–71.
  23. L. Johansson, Industrial by-products and natural substrata as phosphorus sorbents, Environ. Technol., 20 (1999) 309–316.
  24. M. Zapater-Pereyra, E. Malloci, M.A. van Bruggen, P.N.L. Lens, Use of marine and engineered materials for the removal of phosphorus from secondary effluent, Ecol. Eng., 73 (2014) 635–642.
  25. Y. Liu, X. Sheng, Y.H. Dong, Y.J. Ma, Removal of highconcentration phosphate by calcite: effect of sulfate and pH, Desalination, 289 (2012) 66–71.
  26. J. Wu, X. Tang, G. Yang, B.Y. Sun, Q. Yang, Ieee, Removing Phosphorus From Phosphorus-Containing Industrial Wastewater Using Modified Marble Powder as Chemical Precipitant, 2010 4th International Conference on Bioinformatics and Biomedical Engineering, 2010.
  27. K. Haddad, S. Jellali, S. Jaouadi, M. Benltifa, A. Mlayah, A.H. Hamzaoui, Raw and treated marble wastes reuse as low cost materials for phosphorus removal from aqueous solutions: efficiencies and mechanisms, C.R. Chim., 18 (2015) 75–87.
  28. S. Jaouadi, M.A. Wahab, M. Anane, L. Bousselmi, S. Jellali, Powdered marble wastes reuse as a low-cost material for phosphorus removal from aqueous solutions under dynamic conditions, Desal. Water Treat., 52 (2014) 1705–1715.
  29. J.B. Xiong, Y. Qin, E. Islam, M. Yue, W.F. Wang, Phosphate removal from solution using powdered freshwater mussel shells, Desalination, 276 (2011) 317–321.
  30. Z. Brogowski, G. Renman, Characterization of opoka as a basis for its use in wastewater treatment, Pol. J. Environ. Stud., 13 (2004) 15–20.
  31. K. Jóźwiakowski, Experiment of increasing effectiveness of phosphorus removal in a model of wastewater treatment plant, Inżynieria Rolnicza (Agricultural Engineering), 5 (2006) 249–256.
  32. C. Nilson, Phosphorus Removal in Reactive Filter Materials– Factors Affecting the Sorption Capacity TRITA LWR LIC 2066, 2012.
  33. A. Bus, A. Karczmarczyk, Properties of lime-siliceous rock opoka as reactive material to remove phosphorous from water and wastewater, Infrastruktura i Ekologia Terenów Wiejskich (Infrastructure and Ecology of Rural Areas), (2014) 227–238.
  34. A. Kaczmarczyk, K. Woja, P. Bliska, A. Baryła, A. Bus, The efficiency of filtration materials (Polonite® and Leca®) supporting phosphorus removal in on site treatment systems with wastewater infiltration, Infrastruktura i Ekologia Terenów Wiejskich (Infrastructure and Ecology of Rural Areas), 4 (2017) 1401–1413.
  35. A. Renman, G. Renman, Long-term phosphate removal by the calcium-silicate material Polonite in wastewater filtration systems, Chemosphere, 79 (2010) 659–664.
  36. M. Kasprzyk, M. Gajewska, Phosphorus removal by application of natural and semi-natural materials for possible recovery according to assumptions of circular economy and closed circuit of P, Sci. Total Environ., 650 (2019) 249–256.
  37. P. Bartczak, Assessment of the Sorption Capacity of Natural Materials in Removing Selected Inorganic and Organic Compounds, Taking into Account Water Applications, 2017.
  38. A. Hedstrom, Wollastonite as reactive filter medium for sorption of wastewater ammonium and phosphorus, Environ. Technol., 27 (2006) 801–809.
  39. Y. Zhang, X.Y. Kou, H.S. Lu, X.J. Lv, The feasibility of adopting zeolite in phosphorus removal from aqueous solutions, Desal. Water Treat., 52 (2014) 4298–4304.
  40. G.F. Li, M. Yang, X.M. Ding, W. Tan, G.Z. Li, S.J. Fang, H.B. Wang, Study on sodium functionalized ultrasonic-diatomite and its performance for phosphorus removal, Desal. Water Treat., 237 (2021) 64–76.
  41. L.Y. Li, H. Zhang, D.Q. Wang, Influencing Factors of Limestone Sorption and its Usage in Advanced Wastewater Treatment for Phosphorus Removal, M. Nelles, K. Wu, J. Cai, J.J. Cheng, Eds., Proceedings of the 4th International Conference on Environmental Technology and Knowledge Transfer, Chinese German Cent Environ Technol & Knowl Transfer-Cetk, Hefei, 2012, pp. 316–321.
  42. D.H. Kwak, Phosphorus removal characteristics of chemical coagulation process to decrease phosphorus loadings in stream water from agricultural area, Desal. Water Treat., 169 (2019) 268–278.