The critical constants for water are `374^(@)C`, 218 atm and 0.0566 litre `mol^(-1)`. Calculate `a' and `b' of water

The molal boiling point constant for water is 0.513^(@)C kgmol^(-1) . When 0.1 mole of sugar is dissolved in 200 ml of water , the solution boils under a pressure of one atmosphere at

Vanderwaal's constants for hydrogen chloride gas are a = 3.67 atm lit^(-2) and b = 40.8 ml mol^(-1) . Find the critical temperature and critical pressure of the gas.

Standard enthaply of vaporisation Delta_(vap)H^(theta) for water at 100^(@)C is 40.66 kJ mol^(-1) . The internal energy of vapourisation of water at 100^(@)C (in kJ mol^(-1) ) is :

For a pressure at 1.2 atm, calculate the pressure head of water.

(a) Define the following terms : (i) Molarity (ii) Molal elevation constant (K_(b)) (b) A solution containing 15 g urea (molar mass = 60 g mol^(-1) ) per litre of solution in water has same osmotic pressure (isotonic) as a solution of glucose (molar mass = 180 g mol^(-1) ) in water. Calculate the mass of glucose present in one litte of its solution.

Calculate the critical velocity of water in a tube of diameter 0.25m. Given Reynold number =2500, density of water =10^(3)kgm^(-3) and" viscosity"=10^(-3)Nsm^(-2) .

At constant pressure certain quantity of water at 24^(@)C is heated. It was observed that the rise of temperature was found to be 4^(@)C per minute. Calculate the time required to rise the temperature of water to 100^(@)C at sea level by using formula.