Study on phenol adsorption onto Fe-MIL101 in aqueous solution
Tóm tắt
Từ khóa
Tài liệu tham khảo
Babich H., Davist D.L. (1981), Phenol: A review of Environmental and Helath Risks, Regulatory Toxicology and Pharmacology 1, pp. 90-109.
Banat F.A., Al-Bashir B., Al-Asheh S., Hayajneh O. (2000), Adsorption of phenol by bentonite, Environmental Pollution 107, pp. 391-398.
Bhattacharjee S., Chen C., Ahn W. (2014), Chromium terephthalate metal–organic framework MIL-101: synthesis, functionalization, and applications for adsorption and catalysis, RSC Advances 4, pp. 52500—52525.
Chaouati N., Soualah A., Chater M. (2013), Adsorption of phenol from aqueous solution onto zeolites Y modified by silylation, Comptes Rendus Chimie 16, pp. 222-228.
Duan M.J., Guan Z., Ma Y.W., Wan J.Q., Wang Y., Qu Y.F. (2017), A novel catalyst of MIL-101(Fe) doped with Co and Cu as persulfate activator: synthesis, characterization, and catalytic performance, Chemical Papers 72(1), pp. 235-250.
Frey G., Serre C., Draznieks C.M., Millange F., Surble S., Dutour J., Margiolaki I. (2004), A hybrid solid with giant pores prepared by a combination of targeted chemistry, simulation, and powder diffraction, Angewandte Chemie International Edition, 43 (46), pp. 6296–6301.
Hassan H.M.A., Betiha M.A., Mohamed S.K., El-Sharkawy E.A., Ahmed E.A (2017), Stable and recyclable MIL-101(Cr) – Ionic liquid based hybrid nanomaterials as heterogeneous catalyst, Journal of Molecular Liquids, 236, pp. 385 –3943
Hwang Y.K., Hong D.Y., Chang J.S., Seo H., Yoon M., Kim J., Jhung S.H., Serre C., Ferey G. (2009), Selective sulfoxidation of aryl sulfides by coordinatively unsaturated metal centers in chromium carboxylate MIL-101, Applied Catalysis A: General, 358, pp. 249-253.
Leng K., Sun Y., Li X., Sun S., Xu W. (2016), Rapid Synthesis of Metal−Organic Frameworks MIL-101(Cr) Without the Addition of Solvent and Hydrofluoric Acid, Crystal Growth and Design 16, pp. 1168-1171.
Li Y., Xie Q., Hu Q., Li C., Huang Z., Yang X., Guo H. (2016), Surface modification of hollow magnetic Fe3O4@NH2-MIL-101(Fe) derived from metal-organic frameworks for enhanced selective removal of phosphates from aqueous solution, Scientific Reports 6, pp. 30651-30661.
Luan Y., Qi Y., Gao H., Andriamitantsoa R.S., Zheng N., Wang G. (2015), A general post-synthetic modification approach of amino-tagged metal-organic frameworks to access efficient catalysts for the Knoevenagel condensation reaction, Journal of Materials Chemistry A, 33, pp. 1-13.
Martino C.J., Savage P.E. (1997), Thermal decomposition of substituted phenols in supercritical water, Industrial & Engineering Chemistry Research 36(5), pp. 1385-1390.
Polaert I., Wilhelm A.M., Delmas H. (2002), Phenol wastewater treatment by a two-step adsorption–oxidation process on activated carbon, Chemical Engineering Science 57, pp. 1585-1590.
Santiago-Portillo A., Navalon S., Cirujano F.G., Xamena F.L., Alvaro M., Garcia H. (2015), MIL-101 as reusable solid catalyst for autooxidation of benzylic hydrocarbons in the absence of additional oxidizing reagent, ACS Catalysis 5 (6), pp. 3216–3224.
Tezcan Un U., Gul A. (2017), Removal of phenol by adsorption, International Journal of Advances in Science Engineering and Technology 5(2), pp. 38-40.
Xie K., Shan C., Qi J., Qiao S., Zeng Q., Zhang L. (2014), Study of adsorptive removal of phenol by MOF-5, Desalination and Water Treatment, pp. 1-6.
Zalomaeva O.V., Kovalenko K.A., Chesalov Y.A., Mel'Gunov M.S. (2011), Iron tetrasulfophthalocyanine immobilized on metal organic framework MIL-101: synthesis, characterization and catalytic properties, The Royal Society of Chemistry 40, pp.1441-1444.
Zhoua H., Kitagawa S. (2014), Metal–Organic Frameworks (MOFs), Chemical Society Reviews 43, pp. 5415-5418.