= The vapor pressure of component A'is 300.3 torr, and that of component B is 70torr at 35 °C. A Solution of A and B at 35 °C with x = 0.300 has a vaporpressure of 70.3 torr and a vapor composition of x = 0.275.(i) Calculate yand a, for component A and for component B in this solution.%3D-tin.(ii) Calculate u - Hi for each component of this solution.(iii) Calculate AG for the mixing of 0.200 mole of liquid component B and 0.800mole of liquid chloroform at 35 "c.(iv) Calculate AGmix for the corresponding ideal solution.

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= The vapor pressure of component A'is 300.3 torr, and that of component B is 70 torr at 35 °C. A Solution of A and B at 35 °C with x = 0.300 has a vapor %3D pressure of 70.3 torr and a vapor composition of x = 0.275. (i) Calculate yand a, for component A and for component B in this solution. %3D -Itin. (ii) Calculate u - Hi for each component of this solution. (ii) Calculate AG for the mixing of 0.200 mole of liquid component B and 0.800 mole of liquid chloroform at 35 "c. (iv) Calculate AG,mlx for the corresponding ideal solution.

= The vapor pressure of component A'is 300.3 torr, and that of component B is 70 torr at 35 °C. A Solution of A and B at 35 °C with x = 0.300 has a vapor %3D pressure of 70.3 torr and a vapor composition of x = 0.275. (i) Calculate yand a, for component A and for component B in this solution. %3D -Itin. (ii) Calculate u - Hi for each component of this solution. (ii) Calculate AG for the mixing of 0.200 mole of liquid component B and 0.800 mole of liquid chloroform at 35 "c. (iv) Calculate AG,mlx for the corresponding ideal solution.

Chemistry: Principles and Practice

3rd Edition

ISBN:9780534420123

Author:Daniel L. Reger, Scott R. Goode, David W. Ball, Edward Mercer

Publisher:Daniel L. Reger, Scott R. Goode, David W. Ball, Edward Mercer

Chapter12: Solutions

Section: Chapter Questions

Problem 12.39QE: The density of a 3.75 M aqueous sulfuric acid solution in a car battery is 1.225 g/mL. Express the...

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The density of a 3.75 M aqueous sulfuric acid solution in a car battery is 1.225 g/mL. Express the concentration of the solution in molality, mole fraction H2SO2, and mass percentage of H2SO4.
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