Benzene–dioxane association. The excess molar enthalpy of (cyclohexane + dioxane)(g) and (benzene + dioxane)(g) from the temperature (373.2 to 432.2) K

cyclohexane q diethyl ketone g and benzene q diethyl ketone g at standard atmospheric pressure over the temperature range 373.2 K to 423.2 K. The non-ideality of the cyclohexane and benzene was fitted using the Kihara potential, and that of the diethyl ketone using the Ž Stockmayer potential. Cross-

cyclohexane q dichloromethane g and benzene q dichloromethane g at standard Ž . atmospheric pressure over the temperature range 353.2 to 453.2 K. The non-ideality of the cyclohexane and benzene was fitted using the Kihara potential, and that of the dichloromethane using the Stockmayer potential. Cro

cyclohexane q tetrachloromethane g and benzene q tetrachloromethane g at standard atmospheric pressure over the temperature range 353.2 K to 423.2 K. The non-ideality of the cyclohexane, benzene, and tetrachloromethane was fitted using the Kihara potential. Cross-Ž . Ž . 1 r 2 terms were calculated

cyclohexane q diethyl ether g and benzene q diethyl ether g at standard atmospheric pressure over the temperature range 353.2 K to 423.2 K. The non-ideality of the cyclohexane and benzene was fitted using the Kihara potential, and that of the diethyl ether using the Ž Stockmayer potential. Cross-ter

A differential flow mixing calorimeter has been used to measure the excess molar enthalpy H E m of (nitrogen + dimethyl ketone)(g) at standard atmospheric pressure over the temperature range 333.2 K to 423.2 K. The measurements are analysed using the corresponding states correlation of Tsonopoulos u

Values of the second virial coefficient B of benzene and cyclohexane have been obtained from measurements of the excess molar enthalpy H E m of {yN2 + (1y)C6H6} and {yN2+(1-y)C6H12} measured at standard atmospheric pressure over the temperature range 333.2 to 433.2 K. In a hypothetical mixture of an