[1] C. Du, Z. Zhang, G. Yu, H. Wu, H. Chen, L. Zhou, Y. Zhang, Y. Su, S. Tan, L. Yang, J. Song, S. Wang, A review of metal organic framework (MOFs)-based materials for antibiotics removal via adsorption and photocatalysis, Chemosphere, 272 (2021) 129501.
[2] H. Zhang, P. Liu, Y. Feng, F. Yang, Fate of antibiotics during wastewater treatment and antibiotic distribution in the effluent-receiving waters of the Yellow Sea, northern China, Marine pollution bulletin, 73 (2013) 282-290.
[3] M. Foroughi, H.R.S. Arezoomand, A.R. Rahmani, G. Asgari, D. Nematollahi, K. Yetilmezsoy, M.R. Samarghandi, Electrodegradation of tetracycline using stainless steel net electrodes: Screening of main effective parameters and interactions by means of a two-level factorial design, Korean Journal of Chemical Engineering, 34 (2017) 2999-3008.
[4] Y. Chao, L. Yang, H. Ji, W. Zhu, J. Pang, C. Han, H. Li, Graphene‐analogue molybdenum disulfide for adsorptive removal of tetracycline from aqueous solution: equilibrium, kinetic, and thermodynamic studies, Environmental Progress & Sustainable Energy, 36 (2017) 815-821.
[5] G. Hou, X. Hao, R. Zhang, J. Wang, R. Liu, C. Liu, Tetracycline removal and effect on the formation and degradation of extracellular polymeric substances and volatile fatty acids in the process of hydrogen fermentation, Bioresource technology, 212 (2016) 20-25.
[6] S. Rodriguez-Mozaz, S. Chamorro, E. Marti, B. Huerta, M. Gros, A. Sànchez-Melsió, C.M. Borrego, D. Barceló, J.L. Balcázar, Occurrence of antibiotics and antibiotic resistance genes in hospital and urban wastewaters and their impact on the receiving river, Water research, 69 (2015) 234-242.
[7] L. Hou, H. Zhang, X. Xue, Ultrasound enhanced heterogeneous activation of peroxydisulfate by magnetite catalyst for the degradation of tetracycline in water, Separation and Purification Technology, 84 (2012) 147-152.
[8] A. Garcia-Rodríguez, V. Matamoros, C. Fontàs, V. Salvadó, The influence of light exposure, water quality and vegetation on the removal of sulfonamides and tetracyclines: a laboratory-scale study, Chemosphere, 90 (2013) 2297-2302.
[9] Q. Yi, Y. Gao, H. Zhang, H. Zhang, Y. Zhang, M. Yang, Establishment of a pretreatment method for tetracycline production wastewater using enhanced hydrolysis, Chemical Engineering Journal, 300 (2016) 139-145.
[10] F. Liu, W. Zhang, W. Chen, J. Wang, Q. Yang, W. Zhu, J. Wang, One-pot synthesis of NiFe2O4 integrated with EDTA-derived carbon dots for enhanced removal of tetracycline, Chemical Engineering Journal, 310 (2017) 187-196.
[11] J. Ou, M. Mei, X. Xu, Magnetic adsorbent constructed from the loading of amino functionalized Fe3O4 on coordination complex modified polyoxometalates nanoparticle and its tetracycline adsorption removal property study, Journal of Solid State Chemistry, 238 (2016) 182-188.
[12] H. Kaur, G. Hippargi, G.R. Pophali, A. Bansiwal, Biomimetic lipophilic activated carbon for enhanced removal of triclosan from water, Journal of Colloid and Interface Science, 535 (2019) 111-121.
[13] L. Bulgariu, L.B. Escudero, O.S. Bello, M. Iqbal, J. Nisar, K.A. Adegoke, F. Alakhras, M. Kornaros, I. Anastopoulos, The utilization of leaf-based adsorbents for dyes removal: A review, Journal of Molecular Liquids, 276 (2019) 728-747.
[14] A.A. Oladipo, M.A. Abureesh, M. Gazi, Bifunctional composite from spent “Cyprus coffee” for tetracycline removal and phenol degradation: Solar-Fenton process and artificial neural network, International journal of biological macromolecules, 90 (2016) 89-99.
[15] H. Pignon, C. Brasquet, P. Le Cloirec, Coupling ultrafiltration and adsorption onto activated carbon cloth: application to the treatment of highly coloured wastewaters, Water science and technology, 42 (2000) 355-362.
[16] L.C. Oliveira, R.V. Rios, J.D. Fabris, V. Garg, K. Sapag, R.M.J.C. Lago, Activated carbon/iron oxide magnetic composites for the adsorption of contaminants in water, 40 (2002) 2177-2183.
[17] R.C. Bansal, M. Goyal, Activated carbon adsorption, CRC press, 2005.
[18] J.-W. Shim, S.-J. Park, S.-K.J.C. Ryu, Effect of modification with HNO3 and NaOH on metal adsorption by pitch-based activated carbon fibers, 39 (2001) 1635-1642.
[19] S. Dashamiri, M. Ghaedi, K. Dashtian, M.R. Rahimi, A. Goudarzi, R. Jannesar, Ultrasonic enhancement of the simultaneous removal of quaternary toxic organic dyes by CuO nanoparticles loaded on activated carbon: central composite design, kinetic and isotherm study, Ultrasonics sonochemistry, 31 (2016) 546-557.
[20] P. Meng, X. Fang, A. Maimaiti, G. Yu, S.J.C. Deng, Efficient removal of perfluorinated compounds from water using a regenerable magnetic activated carbon, 224 (2019) 187-194.
[21] G. Feiqiang, L. Xiaolei, J. Xiaochen, Z. Xingmin, G. Chenglong, R. Zhonghao, Characteristics and toxic dye adsorption of magnetic activated carbon prepared from biomass waste by modified one-step synthesis, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 555 (2018) 43-54.
[22] E. Aliyari, M. Alvand, F.J.R.A. Shemirani, Modified surface-active ionic liquid-coated magnetic graphene oxide as a new magnetic solid phase extraction sorbent for preconcentration of trace nickel, 6 (2016) 64193-64202.
[23] J. Chen, Y. Wang, Y. Huang, K. Xu, N. Li, Q. Wen, Y.J.A. Zhou, Magnetic multiwall carbon nanotubes modified with dual hydroxy functional ionic liquid for the solid-phase extraction of protein, 140 (2015) 3474-3483.
[24] M. Muneeb Ur Rahman Khattak, M. Zahoor, B. Muhammad, F.A. Khan, R. Ullah, N.M. AbdEI-Salam, Removal of Heavy Metals from Drinking Water by Magnetic Carbon Nanostructures Prepared from Biomass %J Journal of Nanomaterials, 2017 (2017) 10.
[25] M. Muneeb Ur Rahman Khattak, M. Zahoor, B. Muhammad, F.A. Khan, R. Ullah, N.M.J.J.o.N. AbdEI-Salam, Removal of heavy metals from drinking water by magnetic carbon nanostructures prepared from biomass, 2017 (2017).
[26] Z. Noorimotlagh, S.A. Mirzaee, S.S. Martinez, S. Alavi, M. Ahmadi, N.J.C.E.R. Jaafarzadeh, Design, Adsorption of textile dye in activated carbons prepared from DVD and CD wastes modified with multi-wall carbon nanotubes: Equilibrium isotherms, kinetics and thermodynamic study, (2018).
[27] Q. Zhou, Z. Li, C. Shuang, A. Li, M. Zhang, M. Wang, Efficient removal of tetracycline by reusable magnetic microspheres with a high surface area, Chemical Engineering Journal, 210 (2012) 350-356.
[28] N. Gharibzadeh, E. Fatehifar, R. Alizadeh, A. Haghlesan, M. Chavoshbashi, Modeling and optimization of removal of toluene from aqueous solutions using iron oxide nanoparticles by RSM method, Modares Civil Engineering Journal, 16 (2016) 203-213.
[29] J. Parsa, M. Abbasi, Modeling and optimizing of sonochemical degradation of Basic Blue 41 via response surface methodology, Open Chemistry, 8 (2010) 1069-1077.
[30] H. Zarei, A. Mahvi, S. Nasseri, R. Nabizadeh Noudehi, F. Shemirani, Modeling adsorption on fluoride and application of Box–Behnken design and response surface methodology for arsenic (V) removal from aqueous solution using Nano-Scale Alumina on Multi Walled Carbon Nanotube, Iranian Journal of Health and Environment, 8 (2015) 309-322.
[31] S. Ahmadi, L. Mohammadi, A. Rahdar, S. Rahdar, R. Dehghani, C.A. Igwegbe, G.Z. Kyzas, Acid dye removal from aqueous solution by using neodymium(III) oxide nanoadsorbents, Nanomaterials, 10 (2020) Article no. 556.
[32] W.W. Ngah, M. Hanafiah, Adsorption of copper on rubber (Hevea brasiliensis) leaf powder: Kinetic, equilibrium and thermodynamic studies, Biochemical Engineering Journal, 39 (2008) 521-530.
[33] O. Gulnaz, A. Kaya, S. Dincer, The reuse of dried activated sludge for adsorption of reactive dye, Journal of Hazardous Materials, 134 (2006) 190-196.
[34] C. Chen, X. Feng, S. Yao, Ionic liquid-multi walled carbon nanotubes composite tablet for continuous adsorption of tetracyclines and heavy metals, Journal of Cleaner Production, 286 (2021) 124937.
[35] S. Rakshit, D. Sarkar, E.J. Elzinga, P. Punamiya, R. Datta, Surface complexation of oxytetracycline by magnetite: Effect of solution properties, Vadose Zone Journal, 13 (2014) 1-10.
[36] R.A. Figueroa, A. Leonard, A.A. MacKay, Modeling tetracycline antibiotic sorption to clays, Environmental science & technology, 38 (2004) 476-483.
[37] S. Rakshit, E.J. Elzinga, R. Datta, D. Sarkar, In situ attenuated total reflectance Fourier‐transform infrared study of oxytetracycline sorption on magnetite, Journal of environmental quality, 42 (2013) 822-827.
[38] C. Zhao, W. Yin, J. Xu, Y. Zhang, D. Shang, Z. Guo, Q. Wang, J. Wang, Q. Kong, Removal of Tetracycline from Water Using Activated Carbon Derived from the Mixture of Phragmites australis and Waterworks Sludge, ACS Omega, 5 (2020) 16045-16052.
[39] G. Zhao, J. Li, X. Ren, C. Chen, X. Wang, Few-layered graphene oxide nanosheets as superior sorbents for heavy metal ion pollution management, Environmental science & technology, 45 (2011) 10454-10462.
[40] S. Ahmadi, L. Mohammadi, A. Rahdar, S. Rahdar, R. Dehghani, C.A. Igwegbe, G.Z. Kyzas, Acid dye removal from aqueous solution by using neodymium (III) oxide nanoadsorbents, Nanomaterials, 10 (2020) 556.
[41] G.T. Güyer, N.H. Ince, Degradation of diclofenac in water by homogeneous and heterogeneous sonolysis, Ultrasonics sonochemistry, 18 (2011) 114-119.
[42] R. Deng, D. Huang, G. Zeng, J. Wan, W. Xue, X. Wen, X. Liu, S. Chen, J. Li, C. Liu, Decontamination of lead and tetracycline from aqueous solution by a promising carbonaceous nanocomposite: Interaction and mechanisms insight, Bioresource technology, 283 (2019) 277-285.
[43] J. Rivera-Utrilla, C.V. Gómez-Pacheco, M. Sánchez-Polo, J.J. López-Peñalver, R. Ocampo-Pérez, Tetracycline removal from water by adsorption/bioadsorption on activated carbons and sludge-derived adsorbents, Journal of Environmental Management, 131 (2013) 16-24.
[44] H. Zarei, A. Mahvi, S. Nasseri, R.N. Noudehi, F. Shemirani, Modeling adsorption on fluoride and application of Box-Behnken design and response surface methodology for arsenic (V) removal from aqueous solution using nano-scale alumina on multi walled carbon nanotube, Iranian Journal of Health and Environment, 8 (2015).
[45] L. Ji, W. Chen, L. Duan, D. Zhu, Mechanisms for strong adsorption of tetracycline to carbon nanotubes: a comparative study using activated carbon and graphite as adsorbents, Environmental science & technology, 43 (2009) 2322-2327.
[46] L. Ji, Y. Wan, S. Zheng, D. Zhu, Adsorption of tetracycline and sulfamethoxazole on crop residue-derived ashes: implication for the relative importance of black carbon to soil sorption, Environmental Science & Technology, 45 (2011) 5580-5586.
[47] J. Chen, W. Chen, D. Zhu, Adsorption of Nonionic Aromatic Compounds to Single-Walled Carbon Nanotubes: Effects of Aqueous Solution Chemistry, Environmental Science & Technology, 42 (2008) 7225-7230.
[48] W. Chen, L. Duan, D. Zhu, Adsorption of Polar and Nonpolar Organic Chemicals to Carbon Nanotubes, Environmental Science & Technology, 41 (2007) 8295-8300.
[49] D. Zhu, J.J. Pignatello, Characterization of Aromatic Compound Sorptive Interactions with Black Carbon (Charcoal) Assisted by Graphite as a Model, Environmental Science & Technology, 39 (2005) 2033-2041.
[50] J. Chang, Z. Shen, X. Hu, E. Schulman, C. Cui, Q. Guo, H. Tian, Adsorption of Tetracycline by Shrimp Shell Waste from Aqueous Solutions: Adsorption Isotherm, Kinetics Modeling, and Mechanism, ACS Omega, 5 (2020) 3467-3477.
[51] T. Chen, L. Luo, S. Deng, G. Shi, S. Zhang, Y. Zhang, O. Deng, L. Wang, J. Zhang, L. Wei, Sorption of tetracycline on H3PO4 modified biochar derived from rice straw and swine manure, Bioresource Technology, 267 (2018) 431-437.
[52] B. Debnath, M. Majumdar, M. Bhowmik, K.L. Bhowmik, A. Debnath, D.N. Roy, The effective adsorption of tetracycline onto zirconia nanoparticles synthesized by novel microbial green technology, Journal of Environmental Management, 261 (2020) 110235.
[53] W. Xiong, G. Zeng, Z. Yang, Y. Zhou, C. Zhang, M. Cheng, Y. Liu, L. Hu, J. Wan, C. Zhou, R. Xu, X. Li, Adsorption of tetracycline antibiotics from aqueous solutions on nanocomposite multi-walled carbon nanotube functionalized MIL-53(Fe) as new adsorbent, Science of The Total Environment, 627 (2018) 235-244.
[54] J. Dai, X. Meng, Y. Zhang, Y. Huang, Effects of modification and magnetization of rice straw derived biochar on adsorption of tetracycline from water, Bioresource Technology, 311 (2020) 123455.
[55] X. Zhang, Y. Li, M. Wu, Y. Pang, Z. Hao, M. Hu, R. Qiu, Z. Chen, Enhanced adsorption of tetracycline by an iron and manganese oxides loaded biochar: Kinetics, mechanism and column adsorption, Bioresource Technology, 320 (2021) 124264.
[56] H. Zhu, T. Chen, J. Liu, D. Li, Adsorption of tetracycline antibiotics from an aqueous solution onto graphene oxide/calcium alginate composite fibers, RSC Advances, 8 (2018) 2616-2621.
[57] A.A. Mohammed, S.L. Kareem, Adsorption of tetracycline fom wastewater by using Pistachio shell coated with ZnO nanoparticles: Equilibrium, kinetic and isotherm studies, Alexandria Engineering Journal, 58 (2019) 917-928.
[58] B. Li, Y. Huang, Z. Wang, J. Li, Z. Liu, S. Fan, Enhanced adsorption capacity of tetracycline on tea waste biochar with KHCO3 activation from aqueous solution, Environmental Science and Pollution Research, (2021).
[59] W. Gu, X. Huang, Y. Tian, M. Cao, L. Zhou, Y. Zhou, J. Lu, J. Lei, Y. Zhou, L. Wang, Y. Liu, J. Zhang, High-efficiency adsorption of tetracycline by cooperation of carbon and iron in a magnetic Fe/porous carbon hybrid with effective Fenton regeneration, Applied Surface Science, 538 (2021) 147813.
[60] B. Turan, M. Bugdayci, K. Benzesik, P. Demircivi, Synthesis of Eu doped SrAl2O4 composite: adsorption characteristics on tetracycline and ciprofloxacin antibiotics, Separation Science and Technology, (2021) 1-12.
[61] M. Yuan, C. Li, B. Zhang, J. Wang, J. Zhu, J. Ji, Y. Ma, A mild and one-pot method to activate lignin-derived biomass by using boric acid for aqueous tetracycline antibiotics removal in water, Chemosphere, 280 (2021) 130877.