Magnetic silica nanoparticles for the removal of Pb⁺² from water

Zero valent iron impregnated silica nanoparticles (Fe⁰/n-SiO₂) were synthesized using sol-gel process followed by supercritical drying, wet impregnation and hydrogen reduction. The synthesized nanoparticles were characterized by nitrogen Brunauer–Emmett–Teller (N₂-BET), Scanning Electron Microscopy, Transmission Electron Microscopy, Scanning Electron Microscopy with Energy-Dispersive X-ray spectroscopy, Vibrating Sample Magnetometer and X-ray diffraction techniques. Prepared samples were found to be magnetic with ultra-low density (0.048 g/mL) and high surface area (422 m²/g). Prepared samples were evaluated for adsorptive removal of Pb⁺² (5, 10, 25 and 50 ppm) from contaminated water. Results indicated that the adsorption of Pb⁺² was faster at lower concentrations (5 and 10 ppm) as > 80 % of Pb⁺² was removed within 480 minutes. At higher concentrations, the adsorption was slower, and the removal efficiency of 51.24 and 21.78 % were observed for 25 and 50 ppm Pb⁺² respectively, whereas for bare SiO₂ nanoparticles, it was 39.64 and 14.04 %.

1. Chen J.Z., Tao X.C., Xu J., Zhang T., Liu Z.L. Biosortption of lead, cadmium and mercury by immobilized microcystisaeruginosa in a column. Process Biochemistry, 2005, 40(12), P. 3675–3679.

2. Naeem A., Saddique M.T., Mustafa S., Kim Y., Dilara, B. Cation exchange removal of Pb from aqueous solution by sorption onto NiO. Journal of Hazardous Materials, 2009, 168(1), P. 364–368.

3. Brooks R., Bahadory M., Tovia F., Rostami H. Removal of lead from contaminated water. International Journal of Soil, Sediment and Water, 2010, 3(2), Article 14, P. 1–13,.

4. Ali I. New generation adsorbents for water treatment. Chemical Reviews, 2012, 112, P. 5073–5091.

5. Li X.Q., Elliott D.W., Zhang W.X. Zero-valent iron nanoparticles for abatement of environmental pollutants. Critical Reviews in Solid State and Material Science, 2006, 31, P. 111–122.

6. Crane R., Scott T.B. Nanoscale zero valent iron:future prostectus for an emerging water treatment technology. Journal of Hazardous Materials, 2011, 211-212, P. 112–125.

7. Petala E., Dimos K., Douvalis A., Bakas T., Tucek J., Zboˇril R., Karakassides M.A. Nanoscale zero-valent iron supported on mesoporous silica: Characterization and reactivity for Cr(VI) removal from aqueous solution. Journal of Hazardous Materials, 2013, 26, P. 295–306.

8. Saxena A., Srivastava A.K., Singh B., Kinetics of adsorption of 2-CEES and HD on impregnated silica nanoparticles under static conditions. American Institute of Chemical Engineers Journal, 2009, 55(5), P. 1236–1245.

9. Shukla N., Saxena A., Gupta V., Rawat A.S., Kumar V., Rai P.K., Shrivastava S. Removal of lead from water by using low density metal oxide nanoparticles. Advance Science Engineering and Medicine, 2015, 7(5), P. 298–405.

10. Chang S.S., Clair B., Ruelle J., Beauche J., Renzo F.D., Quignard F., Zhao G.J., Yamamoto H., Gril J. Mesoporosity as a new parameter for understanding tension stress generation in trees. Journal of Experimental Botany, 2009, 60(11), P. 3023–3030.

11. Xu Y.M., Qi J., He D.M., Wang D.M. Chen H.Y. Guan J., Zhang Q.M. Preparation of amorphous silica from oil shale residue and surface modification by silane coupling agent. Oil Shale, 2010, 27(1), P. 37–46.

12. Pelecky D.L.L., Rieke R.D. Magnetic properties of nanostructured materials. Chemistry of Materials, 1996, 8, P. 1770–1783.