Vapor Liquid Equilibrium between (278.15 and 323.15) K and Excess

Alejandro Ansón, Rosa Garriga, Santiago Martínez, Pascual Pérez, and Mariano Gracia. Journal of Chemical & Engineering Data 2005 50 (4), 1478-1483...
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J. Chem. Eng. Data 2004, 49, 224-230

Vapor Liquid Equilibrium between (278.15 and 323.15) K and Excess Functions at T ) 298.15 K for 1-Bromobutane with 1-Octanol or 1-Decanol Rosa Garriga, Santiago Martı´nez, Pascual Pe´ rez, and Mariano Gracia* Departamento de Quı´mica Orga´nica y Quı´mica Fı´sica (A Ä rea de Quı´mica Fı´sica), Facultad de Ciencias, Universidad de Zaragoza, 50009 Zaragoza, Spain

Vapor pressures of (1-bromobutane + 1-octanol or 1-decanol) at several temperatures between (278.15 and 323.15 K) were measured by a static method. The reduction of the vapor pressures to obtain activity coefficients and excess molar Gibbs energies was carried out by fitting the vapor pressure data to the Wilson equation according to Barker’s method. Excess molar enthalpies HE and volumes VE of (1-bromobutane + 1-octanol) were also measured at 298.15 K. VE at 298.15 K was compared with predictions of the ERAS model.

Introduction Hydrogen bonding plays an important role both in fundamental science and in industrial applications.1 Although many experimental and theoretical studies have been directed toward understanding hydrogen bonding, it remains an area of active research. Thermodynamic data of binary mixtures of an alcohol with a second polar component are necessary for a better understanding of hydrogen bonding and for the development and testing of models and theories of associated systems in the liquid state. Following our studies on thermodynamic properties of binary systems of (alcohol + 1-chlorobutane)2-5 or (alcohol + 1-bromobutane),6-8 we report vapor pressures at several temperatures for (1-bromobutane + 1-octanol) and for (1-bromobutane + 1-decanol). Excess enthalpies and excess volumes for (1-bromobutane + 1-octanol) have been measured at T ) 298.15 K. A description of the excess volume according to the ERAS model is presented. Isothermal vapor pressure data were not found for these systems in the literature. Experimental Section Chemicals. All the chemicals were supplied by Aldrich. All the chemicals had low water content, were stored over a molecular sieve (3A), and were used without further purification. The mass fraction purity was checked by gasliquid chromatography and found to be 0.996 for 1-bromobutane, 0.995 for 1-octanol, and 0.986 for 1-decanol. Apparatus and Procedures. The vapor pressure measurements were performed by a static method. The apparatus is similar to that of Marsh,9 except for some experimental details which have been described previously.10,11 Each liquid was degassed by magnetic stirring under its own vapor pressure before mixing, with periodic vacuum pumping of the vapor + air. The mixture cell containing a known mass of the first component was immersed in liquid nitrogen, and a known mass of the second component was added by gravity. The mixture cell, filled with (8 to 10) cm3 of sample in each experiment, was * To whom correspondence should be addressed.

connected to a manometric system, which was evacuated, and then the liquid sample was introduced by gravity into the vapor pressure cell, which is connected to one of the branches of the manometer. To prevent condensation effects on the mercury meniscus, the temperature of the manometer and the connecting tube containing the vapor phase was maintained at 325.0 ( 0.1 K by circulating water from a thermostat. Uncertainties in the mole fractions are estimated to be less than 0.0003. The temperature of the liquid sample was controlled to within (10 mK. Manometric levels were read with a cathetometer to within (0.01 mm, and pressure reproducibility was 10 Pa. A Thermometric 2277 calorimeter, together with two Shimadzu (model LC-10AD) variable speed piston pumps, was used to determine HE at T ) 298.15 K. The precision of the HE measurements is better than (2%. The accuracy of the method was verified with a test on (benzene + cyclohexane).12 The experimental results agreed with the literature data with an accuracy of 20 J‚mol-1, in the worst case. A densimeter (Anton Paar DMA 60/DMA 602) was used for density measurements on the pure liquids and mixtures. The densimeter operates at 298.15 K, and sample density is calculated from the vibration period with an uncertainty of (0.000 02 g‚cm-3. The accuracy for VE is estimated to be 0.002 cm3‚mol-1. Results The molar volumes of the pure components used in the Barker analysis together with the experimental and calculated vapor pressures are presented in Table 1. The second virial coefficient, at T ) 325.0 K, of 1-bromobutane (B11 ) -1200 cm3‚mol-1) was taken from Velasco et al.,17 and those of 1-octanol (B22 ) -19 850 cm3‚mol-1) and 1-decanol (B22 ) -40 560 cm3‚mol-1) were calculated from the Tsonopoulos18 correlation. The interaction virial coefficient was estimated with a cubic combination rule,

1 3 B12 ) (B1/3 + B1/3 22 ) 8 11

(1)

Table 2 presents our vapor pressure measurements together with the activity coefficients γ1 and γ2 of 1-bro-

10.1021/je030168a CCC: $27.50 © 2004 American Chemical Society Published on Web 01/16/2004

Journal of Chemical and Engineering Data, Vol. 49, No. 2, 2004 225 Table 1. Molar Volumes V° and Vapor Pressures P° of the Pure Compounds Used in Barker Analysis 1-bromobutane T



a

1-octanol

P°/kPa



d

1-decanol P°/kPa



d

P°/kPa

K

cm3‚mol-1

b

c

cm3‚mol-1

b

e

cm3‚mol-1

b

e

278.15 283.15 288.15 293.15 298.15 303.15 308.15 313.15 318.15 323.15

105.6f

1.860 2.480 3.265 4.261 5.506 7.039 8.899 11.148 13.872 17.092

1.855 2.477 3.269 4.264 5.502 7.027 8.889 11.143 13.851 17.077

110.5 111.0 111.5 112.1 112.6 113.1 113.6 114.2 114.7 115.3