Katalog Buku Karya Dosen ITATS

In human life, clean water is a need that must be fulfilled. Well, water has the potential to be used as clean water. Previous research indicated that several well water samples in the city of Pasuruan contained Pb (II) ions of 0.15 - 0.23 mg/L [1]. The maximum Pb (II) ion content for clean water is 0.05 mg/L [2]. Pb accumulation in the human body at certain levels will endanger human health [3]. Pb exposure can lead to hyperthyroidism and osteoporosis in women. Pb following the blood flow will settle and join the bone matrix. Pb accumulation in the human body can interfere with activity, growth, metabolism, or reproduction [4]. For the well water used by the community to meet the clean water requirements, it must be treated first. This treatment is intended to reduce the Pb (II) ion content in well water. Several studies have been carried out to reduce the Pb (II) ion content in water. The methods used to reduce Pb (II) ions include evaporation, ion exchange, adsorption, flocculation, electrodialysis, solvent extraction, coprecipitation, and chelation therapy [2][5]. Pb (II) ions can be reduced by activated carbon. In the cation exchanger method, Pb (II) ions can be reduced with synthetic resins, which have high selectivity [6].

M. Chabukdhara, A.K. Nema. (2012). Assessment of Heavy Metal Contamination in Hindon River Sediments: A Chemometric and Geochemical Approach. Chemosphere, vol. 87, no. 8, pp. 945-953.

S. Stefan, I. Meghea. (2014). Mechanism of Simultaneous Removal of Ca2+, Ni2+, Pb2+ and Al3+ Ions from Aqueous Solutions using Purolite S930 Ion Exchange Resin. CR Chimie, vol. 17, pp. 496-502.

A. Pal, T. Nasim, A. Giri, A. (2014) Bandyopadhyay Polyelectrolytic Aqueous Guar Gum for Adsorptive Separation of Soluble Pb(II) from Contaminated Water," Carbohyr. Polym, vol. 110, no. 16, pp. 224-230.

A.N. Nikoloski, K. Ang, D. Li. (2015). Recovery of Platinum Palladium and Rhodium from Acidic Chloride Leach Solutions Using Ion Exchange Resins. Hydrometallurgy, vol. 152, p. 20- 32.

A. Ahmad, J.A. Siddique, MA Laskar, R. Kumar, S.H. Moh-Setapar, A. Khatoon, R.A. Shiekh. (2015). New Generation Amberlite XAD Resin for The Removal of Metal Ions: A Review. Journal of Environmental Sciences, vol. 31, p. 104-123.

A. Agrawal, K.K. Sahu. (2006). Separation and Recovery of Lead from A Mixture of Some Heavy Metals Using Amberlite IRC 718 Chelating Resin. Journal of Hazardous Materials, vol. 13. B133, pp. 299-303.

J. Pérez-Arantegui, J. Molera, A. Larrea et al. (2001). Luster pottery from the thirteenth century to the sixteenth century: a nanostructured thin metallic film,” Journal of the American Ceramic Society, vol. 84, no. 2, pp. 442–446, 2001.

S. Padovani, C. Sada, P. Mazzoldi et al. (2003). Copper in glazes of renaissance luster pottery: nanoparticles, ions, and local environment. Journal of Applied Physics, vol. 93, no. 12, pp. 10058–10063.

S. Padovani, I. Borgia, B. Brunetti et al. (2004). Silver and copper nanoclusters in the lustre decoration of Italian Renaissance pottery: an EXAFS study. Applied Physics A, vol. 79, no. 2, pp. 229–233.

Letho, J., and Harjula, R. (2005). Experimantation in ion exchange studies – the problem of getting reliable and comparable results. Reactive and Functional Polymers, vol. 27, no. 6, pp. 121–146.

Schönbächler, M., Carlson, R. W., Horan, M. F., Mock, T. D., and Hauri, E. H. (2007). High precision Ag isotope measurements in geologic materials by multiple- collector ICPMS: an evaluation of dry versus wet plasma. International Journal of Mass Spectrometry, 261, 183–191.

Weiss, D. J., Rehkämper, M., Schoenberg, R., McLaughlin, M., Kirby, J., Cambell, P. G. C., Arnold, T., Peel, K., and Gioia, S. (2008). Application of nontraditional stable-isotope systems to the study of sources and fate of metals in the environment. Environment Science and Technology, vol. 42, no. 8, pp. 655–664.