References

1. S. Aydin, M.E. Aydin, F. Beduk, B. Fatma, U. Arzu, Removal of antibiotics from aqueous solution by using magnetic Fe₃O₄/red mud-nanoparticles, Sci. Total Environ., 670 (2019) 539–546.
2. F. Ni, J.S. He, Y.B. Wang, Z.K. Luan, Preparation and characterization of a cost-effective red mud/polyaluminum chloride composite coagulant for enhanced phosphate removal from aqueous solutions, J. Water Process Eng., 6 (2015) 158–165.
3. L. Wang, N. Sun, H.H. Tang, W. Sun, A review on comprehensive utilization of red mud and prospect analysis, Minerals, 9 (2019) 362, doi: 10.3390/min9060362.
4. E. Mukiza, L.L. Zhang, X. Liu, N. Zhang, Utilization of red mud in road base and subgrade materials: a review, Resour. Conserv. Recyl., 141 (2019) 187–199.
5. P. Krivenko, O. Kovalchuk, A. Pasko, T. Croymans, M. Hult, G. Luttee, N. Vandevenne, S. Schreurs, W. Schroeyers, Development of alkali activated cements and concrete mixture design with high volumes of red mud, Constr. Build. Mater., 6 (2017) 819–826.
6. C.L. Liu, S.H. Ma, S.L. Zheng, Y. Luo, J. Ding, X.H. Wang, Y. Zhang, Combined treatment of red mud and coal fly ash by a hydro-chemical process, Hydrometallurgy, 175 (2018) 224–231.
7. P. Hu, Y.H. Zhang, F.Z. Lv, W.S. Tong, H. Xin, Z.L. Meng, X.K. Wang, P.K. Chu, Preparation of layered double hydroxides using boron mud and red mud industrial wastes and adsorption mechanism to phosphate, Water Environ. J., 31 (2017) 145–157.
8. B.H. Thagira, P. Karthikeyan, S. Meenakshi, Lanthanum(III) encapsulated chitosan-montmorillonite composite for the adsorptive removal of phosphate ions from aqueous solution, Int. J. Biol. Macromol., 112 (2018) 284–293.
9. C. Tarayre, R. Charlier, A. Delepierre, A. Brognaux, J. Bauwens, F. Francis, M. Dermience, G. Logany, B. Taminiau, G. Daube, P. Compere, E. Meers, E. Michels, F. Delvigne, Looking for phosphate-accumulating bacteria in activated sludge processes: a multidisciplinary approach, Environ. Sci. Pollut. Res., 24 (2017) 8017–8032.
10. D. Yadav, V. Pruthi, P. Kumar, Enhanced biological phosphorus removal in aerated stirred tank reactor using aerobic bacterial consortium, J. Water Process Eng., 13 (2016) 61–69.
11. A.H. Caravelli, G.C. De, N.E. Zaritzky, Effect of operating conditions on the chemical phosphorus removal using ferric chloride by evaluating orthophosphate precipitation and sedimentation of formed precipitates in batch and continuous systems, Chem. Eng. J., 209 (2012) 469–477.
12. P.I. Omwene, M. Kobya, Treatment of domestic wastewater phosphate by electrocoagulation using Fe and Al electrodes: a comparative study, Process Saf. Environ. Prot., 116 (2018) 34–51.
13. S.M. Ding, Q. Sun, X. Chen, Q. Liu, D. Wang, J. Lin, C.S. Zhang, D.C.W. Tsang, Synergistic adsorption of phosphorus by iron in lanthanum modified bentonite (Phoslock®): new insight into sediment phosphorus immobilization, Water Res., 134 (2018) 32–43.
14. B.Q. Zhang, N. Chen, C.P. Feng, Z.Y. Zhang, Adsorption for phosphate by crosslinked/non-crosslinked-chitosan-Fe(III) complex sorbents: characteristic and mechanism, Chem. Eng. J., 353 (2018) 361–372.
15. C.J. Paul, M. Chua, B. Zhang, Effects of competitive ions, humic acid, and pH on removal of ammonium and phosphorous from the synthetic industrial effluent by ion exchange resins, Waste Manage., 22 (2002) 711–719.
16. W.P. Xiong, J. Tong, Z.H. Yang, G.M. Zeng, Y.Y. Zhou, D.B. Wang, P.P. Song, R. Xu, C. Zhang, M. Cheng, Adsorption of phosphate from aqueous solution using iron-zirconium modified activated carbon nanofiber: performance and mechanism, J. Colloid Interface Sci., 493 (2017) 17–23.
17. J. Ye, X.N. Cong, P.Y. Zhang, E. Hoffmann, G.M. Zeng, Y. Liu, W. Fang, Y. Wu, H.B. Zhang, Interaction between phosphate and acid-activated neutralized red mud during adsorption process, Appl. Surf. Sci., 356 (2015) 128–134.
18. Y.W. Cui, J. Li, Z.F. Du, Y.Z. Peng, Cr(VI) adsorption on red mud modified by lanthanum: performance, kinetics and mechanisms, PLoS One, 11 (2016) e0161780, doi: 10.1371/ journal.pone.0161780.
19. A. Bhatnagar, V.J.P. Vilar, C.M.S. Botelho, R.A.R. Boaventura, A review of the use of red mud as adsorbent for the removal of toxic pollutants from water and wastewater, Environ. Technol., 32 (2011) 231–249.
20. W.W. Huang, S.B. Wang, Z.H. Zhu, L. Li, X.D. Yao, V. Rudolph, F. Haghseresht, Phosphate removal from wastewater using red mud, J. Hazard. Mater., 158 (2008) 35–42.
21. G.F. Hulya, C.T.D. Jens, D. Mcconchie, Increasing the arsenate adsorption capacity of neutralized red mud (Bauxsol), J. Colloid Interface Sci., 271 (2004) 313–320.
22. Y. Su, H. Cui, Q. Li, S. Gao, J.K. Shang, Strong adsorption of phosphate by amorphous zirconium oxide nanoparticles, Water Res., 47 (2013) 5018–5026.
23. N. Pitakteeratham, A. Hafuka, H. Satoh, Y. Watanabe, High efficiency removal of phosphate from water by zirconium sulfate-surfactant micelle mesostructure immobilized on polymer matrix, Water Res., 47 (2013) 3583–3590.
24. R. Chitrakar, S. Tezuka, A. Sonoda, K. Sakane, K. Ooi, T. Hirotsu, Selective adsorption of phosphate from seawater and wastewater by amorphous zirconium hydroxide, J. Colloid Interface Sci., 297 (2006) 426–433.
25. APHA, Standard Methods for the Examination of Water and Wastewater, American Public Health Association, USA, 1995.
26. Y.H. Zhan, H.H. Zhang, J.W. Lin, Z. Zhang, J. Gao, Role of zeolite’s exchangeable cations in phosphate adsorption onto zirconium-modified zeolite, J. Mol. Liq., 243 (2017) 624–637.
27. M. Borandegi, A. Nezamzadeh-Ejhieh, Enhanced removal efficiency of clinoptilolite nano-particles toward Co(II) from aqueous solution by modification with glutamic acid, Colloid Surf., A, 479 (2015) 35–45.
28. Y.H. He, H. Lin, Y.B. Dong, L. Wang, Preferable adsorption of phosphate using lanthanum-incorporated porous zeolite: characteristics and mechanism, Appl. Surf. Sci., 426 (2017) 995–1004.
29. K.Y.A. Lin, S.Y. Chen, A.P. Jochems, Zirconium-based metal organic frameworks: highly selective adsorbents for removal of phosphate from water and urine, Mater. Chem. Phys., 160 (2015) 168–176.
30. Z.M. Ren, L.N. Shao, G.S. Zhang, Adsorption of phosphate from aqueous solution using an iron–zirconium binary oxide sorbent, Water Air Soil Pollut., 223 (2012) 4221–4231.
31. J. Wang, Y.P. Liu, P. Hu, R.H. Huang, Adsorption of phosphate from aqueous solution by Zr(IV)-crosslinked quaternized chitosan/bentonite composite, Environ. Prog. Sustainable Energy, 37 (2018) 267–275.
32. J. Lalley, C. Han, X. Li, D.D. Dionysiou, N.M. Nadagouda, Phosphate adsorption using modified iron oxide-based sorbents in lake water: kinetics, equilibrium, and column tests, Chem. Eng. J., 284 (2016) 1386–1396.
33. V.M. Tangde, S.S. Prajapati, B.B. Mandal, N.P. Kulkarni, Study of kinetics and thermodynamics of removal of phosphate from aqueous solution using activated red mud, Int. J. Environ. Res., 11 (2017) 39–47.
34. J. Goscianska, M. Ptaszkowska-Koniarz, M. Frankowski, R. Panek, W. Franus, Removal of phosphate from water by lanthanum-modified zeolites obtained from fly ash, J. Colloid Interface Sci., 513 (2018) 72–81.
35. Y.Z. Li, C.J. Liu, Z.K. Luan, X.J. Peng, C.L. Zhu, Z.Y. Chen, Z.G. Zhang, J.H. Fan, Z.P. Jia, Phosphate removal from aqueous solutions using raw and activated red mud and fly ash, J. Hazard. Mater., 137 (2006) 374–383.
36. T.S.S. Freire, M.W. Clark, M.J. Comarmond, T.E. Payne, A.J. Reichelt-Brushett, G.J. Thorogood, Electroacoustic isoelectric point determinations of bauxite refinery residues: different neutralisation techniques and minor mineral effects, Langmuir, 28 (2012) 11802–11811.
37. P.S. Kumar, L. Korving, M.C.M. Loosdrecht, G.J. Witkamp, Adsorption as a technology to achieve ultra-low concentrations of phosphate: research gaps and economic analysis, Water Res., 4 (2019) 100029, doi: 10.1016/j.wroa.2019.100029.