Research Journal of Chemical Sciences ________________________________________  ISSN 2231-606X   Vol. 1(6), 48-52, Sept. (2011)     Res.J.Chem.Sci. International Science Congress Association  
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Effects of Concentration and Relative Permittivity on the Transport Properties of Sodium Chloride in Pure water and Ethanol-Water Mixed Solvent Media Bhattarai Ajaya* and Sah Santosh KumarDepartment of Chemistry, Mahendra Morang Adarsh Multiple Campus, Tribhuvan University, Biratnagar, NEPAL Available online at: 
www.isca.in
(Received 20th July 2011, revised 26th July 2011, accepted 03rd August 2011)Abstract The measurements on the conductivity of Sodium Chloridein pure water and ethanol-water mixed solvent media containing 0.10, 0.20, 0.30, 0.40 and 0.50 volume fractions of ethanol at room temperature are reported. The concentrations were varied from ~ 0.025 to~0.10 mol.L-1. The results showed a sharp increase in the conductivity with increasing electrolyte concentration. The effects of relative permittivity of the medium on the conductivity are also investigated. Keywords:Mixed solvent media, relative permittivity, conductivity, sodium chloride IntroductionIt is well known that precise conductivity measurements provide important information on ion-ion and ion-solvent interactions. The effect of ion association on the conductance behaviour of electrolytes has been a subject of extensive investigation. Although numerous conductance measurements have been reported in the literature, such studies in mixed solvents are relatively rare. In recent, several studies have reported that the nature of the spherical ions, having a large variation in size in aqueous mixtures of the alcohols, has received considerable attention.  It was reported in the previous work that potassium halides are structure breakers in ethanol-water mixtures and the maximum in breaking power occurs at 0.1 mole fraction of ethanol.  It has been found in the literature that the conductance of sodium nitrate in ethanol - water mixtures at 308.15 K. But no work has been done earlier on the effects of concentration, relative permittivity on the transport properties of sodium chloride in ethanol-water mixed solvent media. This paper deals with the conductance behaviour of Sodium Chloride in pure water and ethanol-water mixtures covering a range of dielectric constant values at room temperature (303.15 K). Material and MethodsEthanol (E. Merck, India) was used for the experimental works. The purified solvent had a density of 0.78097 g.cm and a co-efficient of viscosity of 0.9490 mPa.s at 303.15 K; these values are in good agreement with the literature values6,7. Distilled water with a specific conductance less than 10-6 S.cm-1 at 303.15 K was used for the preparation of the mixed solvents. The physical properties of ethanol-water mixed solvents used in this study at 303.15K are shown in table 1 and those values are also matched with the published works3,8,9.  sodium chloride (NaCl) employed in these investigations was purchased from Ranbaxy chemical company, inc. India. Conductance measurements were carried out on a Pye-Unicam PW 9509 conductivity meter at a frequency of 2000 Hz using a dip-type cell with a cell constant of 1.15 cm-1 and having an uncertainty of 0.01%. The cell was calibrated by the methods10, using aqueous potassium chloride solution.  The measurements were made at room temperature.  The details of the experimental procedure have been described earlier11,12Solutions were prepared and runs were performed to ensure the reproducibility of the results. Due correction was made for the specific conductance of the solvent by subtracting the specific conductance of the relevant solvent medium from those of the electrolyte solutions. In order to avoid moisture pickup, all solutions were prepared in a dehumidified room with utmost care. In all cases, the experiments were performed in three replicates.   Results and DiscussionThe structures of liquid alcohols are much simpler than that of water. They associate much less strongly and form polymeric H-bonded chains, rather than large cluster, which rarely contain 5 to 7 molecules for sterically hindered alcohols13When alcohol and water are mixed there is a minute but measurable heat of solution that is evident. The hydrogen bonding and closer packing of the molecules by the attraction allows a larger number of molecules of the hydrated alcohol to fit into the same space, thus decreasing the overall volume. The density is decreased with the increase of alcohol content for the ethanol-water mixed solvent system (table 1). This behaviour has been found to be similar in the literatures14, 15,16. As a liquid becomes warmer, the molecules spread out more. When the molecules are more spread out, the substance is less dense, as the specific gravity is lower (table1). 
Research Journal of Chemical Sciences _______________________________________________________ ISSN 2231-606X  Vol. 1(6), 48-52, Sept. (2011) Res.J.Chem.Sci. International Science Congress Association 
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Table-1 Properties of Pure water, Ethanol-Water Mixtures Containing 0.10, 0.20, 0.30, 0.40, 0.50  and pure ethanol at 303.15 KT//g.cm-3 / mPa.s D 
Pure water 
303.15 0.99568 0.7975 76.54 
0.10 volume fraction of ethanol 
303.15 0.98405 1.1262 72.00 
0.20 volume fraction of ethanol 
303.15 0.97126 1.4031 67.32 
0.30 volume fraction of ethanol 
303.15 0.95556 1.6731 62.07 
0.40 volume fraction of ethanol 
303.15 0.93856 1.8816 56.89 
0.50 volume fraction of ethanol 
303.15 0.91915 1.9912 51.48 
Pure ethanol 
303.15 0.78097 0.9490 23.89 
Figure-1 Density of ethanol-water mixtures at 303.15 K 
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Research Journal of Chemical Sciences _______________________________________________________ ISSN 2231-606X  Vol. 1(6), 48-52, Sept. (2011) Res.J.Chem.Sci. International Science Congress Association 
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Figure-2 Dielectric constant of ethanol-water mixtures at 303.15 K Figure-3 Viscosity of ethanol-water mixtures at 303.15 K
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Research Journal of Chemical Sciences _______________________________________________________ ISSN 2231-606X  Vol. 1(6), 48-52, Sept. (2011) Res.J.Chem.Sci. International Science Congress Association 
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Figure-4 Specific conductivities of Sodium Chloride as a function of the salt concentration () in 303.15 K. Circle symbols represent experimental values at pure water, square symbols represent experimental values at 0.10 volume fractions of ethanol, triangle symbols represent experimental values at 0.20 volume fractions of  ethanol, closed circle symbols represent experimental values at 0.30 volume fractions of ethanol, closed square symbols represent experimental values at 0.40 volume fractions of ethanol and closed triangle symbols represent experimental values at 0.50 volume fractions of ethanol respectively In ethanol-water mixtures, solvent-solvent interactions play a considerable part and properties of these mixtures cannot always be interpreted on the basis of continuous miscibility of the components in all mixtures. These mixtures possess also pronounced structures which vary with temperature and ethanol content.The plots of figures (1, 2 and 3) show the variation in the density, dielectric constant and viscosity with ethanol content. It is found that the density and dielectric constant decrease with the increase of ethanol (figures 1 and 2). In the case of viscosity, variation with ethanol shows different behaviour (figure 3). It is observed that by increasing ethanol, the viscosity values increase slowly and reach maxmimum between 0.4 to 0.6 volume fractions of ethanol and then again decrease with further addition of ethanol. It has been described in the literature17 that about 0.4 to 0.6 volume fractions of ethanol, the water structure has broken down completely and the free volume is minimum and then, hole formation in the activation process of viscous flow will require maximum energy at this composition.  The experimental specific conductivities of sodium chloride as a function of the salt concentration () at 303.15 K of  pure water and five different ethanol-water mixtures (containing 0.10, 0.20, 0.30, 0.40 and 0.50 volume fractions of ethanol)  are depicted in figure 4 and shows the specific conductivities exhibit a sharp increase with increasing concentration within the concentration range investigated. Obviously, the concentration dependence of the specific conductivity follows the same pattern at all solvent composition investigated. The relative permittivity of the medium decreased at a given temperature with increasing in the ethanol content and this trend has also been seen in the conductivity study18,19,20 of methanol content in water.ConclusionExperimental results for the specific conductivity of solution of sodium chloride in pure water and ethanol-water mixed solvent media have been presented as a function of salt concentration and different percentage composition of (ethanol + water) mixed solvent media. The 
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Research Journal of Chemical Sciences _______________________________________________________ ISSN 2231-606X  Vol. 1(6), 48-52, Sept. (2011) Res.J.Chem.Sci. International Science Congress Association 
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specific conductivities are found to increase with increasing concentration over the entire concentration range investigated whereas the specific conductivities of sodium chloride decrease with decreasing dielectric constant of solvent composition at temperature 303.15 K. Acknowledgement The authors are grateful to Professor Sujeet Kumar Chatterjee at the department of Chemistry, Mahendra Morang Adarsh Multiple Campus, Tribhuvan University, Biratnagar, Nepal for the valuable suggestions and discussions. The authors are also thankful to Mr. Ghanashyam Shrivastav, the Head of Department of Chemistry, Mahendra Morang Adarsh Multiple Campus,Tribhuvan University, Biratnagar, Nepal for providing us the research facilities to conduct this research work. References1.Sokol V., Tomas R. and Tominic I., Conductometric Study of Ammonium Bromide in 2-Butanol + Water Mixtures, Acta Chim. Slov.,  56, 773-779 (2009)2.Janz G.T. and  Tomkins  R.P.T., Non Aqueous Electrolytes Handbook; Academic Press: London, Vol.1 (1972)  3. Lee J.J. and Lee M.D., Conductance of tetraalkyl ammonium halides in ethanol-water mixtures, Korean J. of Chem. Eng., 5(1), 5-13(1988)4. Lee M.D. and Lee J.J., Seoul Univ, Faculty papers, 4(c), 21(1975)5.Chazhoor J.S. and Radhakrishnan T.P., Conductance of sodium nitrate in ethanol-water mixtures at 35°C, J. Phys. Chem., 60, 151-155(1979)6.Lange N.A. and  Dean J.A., Lange's Handbook of Chemistry, 10th ed. McGraw-Hill, New York  (1967)7.Pure Component Properties (Queriable database) Chemical Engineering Research Information Center. http://www.cheric.org/research/kdb/hcprop/cmpsrch.php. Retrieved 12 May (2007)8.Harned H.S.  and Owen B.B., The physical chemistry of electrolytic solutions, Reinhold. N.Y., 234 (1957) 9.Khimenko M.T., Aleksandrov V.V. and Gritsenko, N.N., Zh. Fiz. Khim., 47(11), 2914-2915 (1973)10.Lind J.E., Jr.,  Zwolenik J.J. and  Fuoss R.M.,Calibration of Conductance Cells at 250 C with  Aqueous Solutions of Potassium Chloride,  J.Am.Chem.Soc., 81, 1557-1559 (1959)11.Das B. and Hazra D.K.,Studies on the Viscosities, Conductances and Adiabatic Compressibilities of Some Tetraalkylammonium Perchlorates in 2-Methoxyethanol, Bull. Chem. Soc. Jpn., 65, 3470-3476 (1992) 12.Das B. and Hazra D.K.,Conductometric, Viscometric and Spectroscopic Investigations on the Solvation Phenomena of Alkali-Metal Ions and Ion pairs in 2-Methoxyethanol, J. Phys. Chem.,  99, 269-273 (1995)13.Franks F. and Ives J.G., Quart, Rev. (London), 20, 1 1965)14.Thakur S. K. and Chauhan S., Ultrasonic Velocity and Allied parameters of drug Colimax in aqueous 1-propanol at 298.15K,  J. Chem. Pharm. Res., 3(2), 657-664 (2011)15.Syal V.K., Thakur S.K., Chauhan S. and  Sharma P., Ultrasonic Velocity Studies of Drug Parvon-spas in Mixed Alcohol–Water Solvent Systems at 298.15 K.,International J.  Thermophys., 26, 807-826(2005)16.Bhattarai A.,Chatterjee  S. K., Deo T. K.  and Niraula T. Pd., Effects of Concentration, Temperature and Solvent Composition on the Partial Molar Volumes of Sodium Lauryl Sulfate in Methanol –Water mixed Solvent Media, J. Chem. Eng. Data. Publication Date (Web): July 13 (2011)17.Lee I. and Hyne J.B., Partial Molal Volumes of Tetraalkylammonium chlorides in Ethanol–water mixtures., Can. J. Chem., 46, 2333-2339 (1968)18.Bhattarai A., Nandi P. and Das B., The Effects of Concentration, Relative Permittivity and Temperature  on the Transport Properties of Sodium Polystyrenesulphonate in Methanol-Water Mixed Solvent Media, J.  Pol.  Res., 13, 475-482 (2006)19.Chatterjee A. and  Das B., Electrical Conductances of Tetrabutylammonium Bromide, Sodium Tetraphenylborate, and Sodium Bromide in Methanol (1) + Water (2) Mixtures at (298.15, 308.15, and 318.15) . J. Chem. Eng. Data., 51, 1352-1355 (2006)20.Bhattarai A., Electrical Conductivity of Semidilute Solution of Sodium Polystyrenesulfonate in Methanol-Water Mixtures at Four Different Temperatures: The Scaling Theory Approach., Nepal Journal of Science and Technology (NJST).,9, 163-170 (2008)
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