The osmotic pressure of urea solution at `10^(@)C` is `200 mm`.becomes `105.3 mm` when it is diluted and temperature raised to `25^(@)C`. The extent of dilution is

The osmotic pressure of a 3.5% solution of cane sugar at 150^(@)C is :

At 10^(@)C , the osmotic pressure of urea solution is 500 mm .The solution is diluted and the temperature is raised to 25^(@)C .when the osmotic pressure is found to be 105.3 mm . Determine the extent of dilution.

At 17^(@)C , the osmotic pressure of sugar solution is 580 torr. The solution is diluted and the temperature is raised to 57^(@)C , when the osmotic pressure is found to be 165 torr. The extent of dilution is a.2 times ,b.3 times ,c.4 times ,d.5 times

Osmotic pressure of a sugar solution at 24^(@)C is 2.5 atm. The concentration of the solution in gm mole per litre is :

The osmotic pressure of a solution at 273 K is 2.5 atm. The osmotic pressure of the same solution at 273^(@)C is :

The osmotic pressure of decimolar solution of urea at 27^(@)C is a. 2.49 bar, b.5 bar, c. 3.4 bar, d. 1.25 bar

The vapour pressure of pure benzene at 88^(@)C is 957 mm and that of toluene at the same temperature is 379.5 mm . The composition of benzene-toluene mixture boiling at 88^(@)C will be

2.5 g of a substance is present in 200 mL of solution showing the osmotic pressure of 60 cm Hg at 15^(@)C . Calculate the molecular weight of substance.What will be the osmotic pressure if temperature is raised to 25^(@)C ?

At 27^(@)C .the vapour pressure of an ideal solution containing 1 mole of A and 1 mole and B is 500 mm of Hg . At the same temperature, if 2 mol of B is added to this solution the vapour pressure of solution increases by 50 mm of Hg . The vapour pressure of A and B in their pure states is respectively.