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Densities and viscosities of binary mixtures of Methanol +DMF, Ethanol +DMF, n-Propanol
+DMF, iso-Propanol +DMF, n-Butanol +DMF, iso-Butanol +DMF, tert-Butanol +DMF, nAmyl
alcohol +DMF, iso-Amyl alcohol +DMF and ternary mixtures of n-Propanol +0.02M SDS
in DMF, n-Butanol +0.02M SDS in DMF and n-Amyl alcohol +0.02M SDS in DMF have
been studied over the entire range of composition (0 <X2 < 1) at 298.15- 323.15K with
an interval of 5K except Methanol. Methanol system was studied at 298.15K, 303.15K and
308.15K owing to its lower boiling point.
The excess molar volumes,temperatures. The values ofVEwere calculated from the densities of the mixtures at different temperature. The values of VE for all the systems are negative over the entire range of composition, showing minima at 0.6 mole fraction of Methanol, - 0.2-0.3 mole fraction of Ethanol, - 0.1-0.2 mole fraction of n-Propanol and - 0.2 mole fraction of iso-Propanol, - 0.10.2 mole fraction of n-Butanol, -0.2 mole fraction of iso-Butanol, -0.3 mole fraction of tert-Butanol, -0.2 mole fraction of n-Amyl alcohol and -0.6 mole fraction of iso-Amyl alcohol. The values of JJE
for the most of studied alcohols are negative throughout the whole range of
composition at lower temperature (298.15K-303.15K), but at higher temperature, it shows
positive throughout the whole range of composition.
The observed values of VE for the mixtures have been explained in terms of physical,
chemical, and geometrical contributions. The physical interactions, that is, nonspecific
interactions between the real species present in the mixture, involve mainly dispersion force
giving a positive contribution. The chemical or specific intermolecular interactions result in a
volume decrease and these interactions include formation of hydrogen bonds and other
complex-forming interactions. The structural contributions are mostly negative and arise from
several effects, especially from interstitial accommodation and changes of free volume.
The viscosity coefficients, η of all the above mixtures at all the six different temperatures
have also been determined. The viscosities increase initially slowly up to -0.6 mole fraction
of Ethanol, n-Propanol, iso-Propanol, n-Butanol, iso-Butanol, tert-Butanol, n-Amyl alcohol
and iso-Amyl alcohols and later on, the viscosity increases sharply until that of pure alcohol is
reached specially at lower temperature. For Methanol, viscosity decrease slowly on continued
addition of Methanol. Viscosity decreases with rise of temperature. In pure state the viscosity
of alcohols has been found to be in the order of, tert-Butanol> n-Amyl alcohol> iso-Amyl alcohol>iso-Butanol>n-Butanol> iso-Propanol> n- Propanol> Ethanol> Methanol There is a marked decrease in the viscosity with increase of temperature for all the isomeric studied alcohols. At 298.15K, viscosity is found to be in the order: tert-Butanol> iso-Butano!>n-Butanol
iso-Propanol> n-Propanol, which however changes to
n-Butanol >iso-Butanol> tert-Butanol n-Propanol> iso-Propano! at 323.15K.
This ascribed that the branched chain isomers are less stable than linear chain isomers at
higher temperature and vice versa.
The η E values are found to be positive or negative, indicating that the DMF solutions of
alcohols are non ideal. Excess viscosities are negative at all the temperatures over the entire
range of composition for all the systems except Methanol with minima occurring between
0.6-0.9 mole fraction of n-Propanol, iso-Propanol, n-Butanol, iso-Butanol, tert-Butanol,
n-Amyl alcohol and iso-Amyl alcohol. Excess viscosity of Methanol is positive at all the
temperatures over the entire range of composition and show maxima in the DMF rich region
at 0.2-0.4 mole fraction of Methanol. Excess viscosity of Ethanol is negative and show
minima at 0.4-0.5 mole fraction of Ethanol. The position of maxima and minima virtually
does not change remarkably with the variation of temperature. The heights of the minima are
in the order:
tert-Butanol> n-Amyl alcohol> iso-Amyl alcohol—iso-Butanol>n-Butanol> iso-Propanol> n-
Propanol> Ethanol.
The negative VE, positive and positive interaction parameter e for the DMF
Methanol system may be ascribed that the interaction is strong, namely formation of Fl-bonding
between DMF and Methanol. The negative yE, negative ηE
and negative E for the DMF + rest of the studied alcohols systems indicate that dispersion force is dominant. For the later case,P'E
is negative due to the segmental inclusion of DMF in the interstices of polymolecular
alkanol aggregates. Some disruptive force causing volume expansion may be present, but it is
more than compensated for by volume contraction through the segmental inclusion of DMF.
The thermodynamic parameters such as, free energy (∆GH), enthalpy (∆H'H) and entropy (∆SH)
change of activation for the viscous flow for these systems were determined for the entire
range of composition by using Eyring's equation. The free energy (∆GH) were found to be
positive in magnitude indicating that the kinetic species involved in forming cavities or holes
in the liquid medium is given by the work required in forming the hole against surface tension
of the solution. The excess properties (yE, ηE∆GHE) data have been fitted by the least square
method to the four parameter Redlich-Kister equation and the values of the parameter a1 have
been reported.
Although the value of density and viscosity of the studied systems of 0.02M SDS in DMF
solutions are slightly higher than the pure DMF solutions, but no appreciable change in the
volumetric and viscometric properties were observed by the addition of the surfactants. |
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