Structural evidences of fuel-based pollutants removal from water into high silica zeolites

. Removal of fuel-based compounds from natural water is of considerable interest due to the harmful effects of these pollutants on the environment, even at very low concentration [1]. Among this category of compounds, toluene, 1,2-dichloroethane and methyl-tert-buthyl-ether are of special relevance since are toxic and commonly found in natural water. Adsorption is a reliable alternative to eliminate these organic compounds from wastewaters because of the flexibility of the system, low energy and cheap operation costs [2-7]. This work is a part of a wider project whose purpose is to study the interaction and mobility of ground water pollutants adsorbed in the zeolites pores. Organophilic synthetic zeolites which are cheap and available on the market, differing in topology, channel systems and free window apertures, and fuel-based-pollutants differing in chemical properties and molecular dimensions, were tested. In particular, structural evidences of adsorption from dilute solutions into organophilic zeolite as well as the competitive role of humic monomers, the effect of the temperature in the adsorption processes will be discussed. The selected adsorbents were commercial as-synthesized hydrophobic ZSM-5 and Y zeolites with high SiO2/Al2O3. Kinetics and adsorption isotherm batch data were obtained via Headspace Solid Phase Microextraction-GC. X-ray powders patterns were collected before and after adsorption on a Bruker D8 Advance diffractometer equipped with SOL-X detector. Thermal analyses (TG and DTA) were performed in air up to 900°C at 10°C/min. Infrared spectra were collected on a Thermo Electron Corporation FT Nicolet 5700 Spectrometer. This combined diffractometric, thermogravimetric, chromatographic and spectroscopic study allowed us to: 1) measure the sorption capacity of hydrophobic zeolite materials weighed against organic pollutants dissolved in water; 2) characterise the structure after contaminants adsorption; 3) localise the organic species in the zeolite channel systems; 4) highlight the role of humic monomers in the pollutants removal; 5) probe the interaction between the adsorbate and the zeolite framework. The very favorable adsorption kinetics along with the effective and highly irreversible adsorption into zeolite pores make these cheap and environmental friendly materials applicable for the treatment of water contaminated with fuel-based pollutants. References. [1] Trindade P.V.O., Sobral L.G. , Rizzo A.C.L., Leite S.G.F. (2005) Chemosphere, 58, 515–522; [2] Braschi I., Gatti G., Bisio C., Berlier G., Sacchetto V., Cossi M., Marchese L. Physical Chemistry C 2012, 116: 6943-6952; [3] Sacchetto V., Gatti G., Paul G., Braschi I., Berlier G., Cossi M., Marchese L., Bagatin R., Bisio C. Physical Chemistry Chemical Physics, 2013, 15, 13275-13287; L.Abu-Lail, J. A. Bergendahl, R. W. Thompson, Journal of Hazardous Materials 2010, 178, 363-369. [3] Martucci A., Pasti L., Nassi M., Alberti A., Arletti R., Bagatin R., Vignola R., Sticca, R. (2012) Micropor. Mesopor. Mater. 148, 174-183. [4] Arletti, R., Martucci, A., Alberti, A., Pasti, L., Nassi, M., Bagatin, R. (2012) Journal of Solid State Chemistry, 194, 135-142.[5] Pasti L., Martucci A., Nassi M., Cavazzini A., Alberti A., Bagatin, R. (2012) Microporous and Mesoporous Materials, 160, 182-193.