A mixture of `0.1 mol ` of `Na_(2)O` and `0.1 mol ` of `BaO` is dissolved in `1000 g` of `H_(2)O`. Calculate the vapour pressure of solution at `373 K`.

A solution of sucrose (molar mass =342) is prepared by dissolving 688.4 g in 1000 g of water. Calculate The vapour pressure of solution at 293 K.

30 g of urea (M=60g mol^(-1) ) is dissolved in 846g of water. Calculate the vapour pressure of water for this solution if vapour pressure of pure water at 298 K is 23.8 mm Hg. (b) Write two differences between ideal solutions and non-ideal solutions,

0.1mol of RNH_(2)(K_(b) = 5 xx 10^(-4)) is mixed with 0.08mol of HC1 and diluted to 1L . Calculate the [H^(o+)] in the solution.

The vapour pressure of water at T(K) is 20 mm Hg. The following solutions are prepared at T(K) I. 6 g of urea (molecular weight = 60) is dissolved in 178.2 g of water. II. 0.01 mol of glucose is dissolved in 179.82 g of water. III. 5.3 g of Na_(2)CO_(3) (molecular weight = 106) is dissolved in 179.1 g of water. Identify the correct order in which the vapour pressure of solutions increases

An equilibrium mixture CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) present in a vessel of one litre capacity at 815^(@)C was found by analysis to contain 0.4 mol of CO, 0.3 mol of H_(2)O, 0.2 mol of CO_(2) and 0.6 mol of H_(2) . a. Calculate K_(c) b. If it is derived to increase the concentration of CO to 0.6 mol by adding CO_(2) to the vessel, how many moles must be addes into equilibrium mixture at constant temperature in order to get this change?

A sample of Na_(2)CO_(3).H_(2)O weighing 0.62 g is added to 10 ml of 0.1 N H_(2)SO_(4) solution . The resulting solution will be

100g of liquid A (molar mass 140g "mol"^(-1) ) was dissolved in 1000g of liquid B (molar mass 180g "mol"^(-1) ). The vapour pressure of pure liquid B was found to be 500 torr. Calculate the vapour pressure of pure liquid A and its vapour pressure in the solution If the total vapour pressure of the solution is 475 torr.

4g of O_(2) and 2g " of " H_(2) are confined in a vessel of capacity 1 litre at 0^(@)C . Calculate the total pressure of the gaseous mixture.

At 700 K, CO_(2) and H_(2) react to form CO and H_(2)O . For this purpose, K_(c ) is 0.11 . If a mixture of 0.45 mol of CO_(2) and 0.45 mol of H_(2) is heated to 700 K . (a) Find out amount of each gas at equilibrium. (b) When equilibrium has been reached, another 0.34 mol of CO_(2) and 0.34 mol of H_(2) are added to the reaction mixture. Find the composition of of mixture at new equilibrium.

K_(c ) for CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) at 986^(@)C is 0.63 . A mixture of 1 mol H_(2)O(g) and 3 mol CO (g) is allowed to react to come to an equilibrium. The equilibrium pressure is 2.0 atm. a. How many moles of H_(2) are present at equilibrium ? b. Calculate partial pressure of each gas at equilibrium.