Osmotic pressure of solution (density is 1 g/ml) containing 3g of glucose(molecular weight=180 g) in 60 g of water at `15^(@)C` is

The osmotic pressure of a solution containing 40 g of solute ("molecular mass 246") per litre at 27^(@)C is (R=0.0822 atm L mol^(-1))

Calculate the molality of an aqueous solution containing 3.0g of urea (mol.mass=60) in 250g of water.

Calculate osmotic pressure of a solution obtained by mixing 100 mL of 3.4% solution "(weight/volume)" of urea "(molecular weight 60)" and 100 mL of 1.6% solution "(weight/volume)" of cane sugar "(molecular weight 342)" at 20^(@)C .

Osmotic pressure of a solution containing 7 g of a protein present in deciliter of a solution is 3.3xx10^(-2) bar at 37^(@)C . Calculate the molar mass of protein.

The freezing point (.^(@)C) of a solution containing 0.1 g of K_(3)[Fe(CN)_(6)] (molecular weight 329) on 100 g of water (K_(f)=1.86 K kg mol^(-1))

(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.

The vapour pressure of a solution cont.aning 10 g of a non-electrolyte in 200 g of water at a particular temperature is 2985 Pa. The vapour pressure of pure water at that temperature is 3000 Pa. Calculate the molecular mass of the solute.

Calculate the vapour pressure lowering caused by the addition of 68.4 g of sucrose (molecular mass = 342) to 500 g of water if the vapour pressure of pure water at 25^(@)C is 20.0 mm Hg .