`300 cm^(3)` of an aqueous solution contains `1.26 g` a polymer. The osmotic pressure of such solution at `300 K` is found to be `1.26xx10^(-3)` bar. Calculate the molar mass of the polymer.

200 cm^(3) of an aqueous solution of a protein contains 1.26 g of the protein. The osmotic pressure of such a solution at 300 K is found to be 2.57 xx10^(-3) bar. Calculate the molar mass of the protein.

The osmotic pressure of 6% solution of urea at 300 K is

The osmotic pressure of 8% solution of urea at 300 K is

The osmotic pressure of 5% solution of urea at 300 K is

200 mL of an aqueous solution of a protein contains its 1.26g. The osmotic pressure of this solution at 300K is found to be 2.57 xx 10^(-3) bar. The molar mass of protein will be (R = 0.083 L bar mol^(-1)K^(-1))

Calculate osmotic pressure of 0.1M urea aqueous solution at 300K .

A solution of a polymer containing 5g dm^(-3) was found to give an osmotic pressure of 600 Nm^(-2) (4.5 mm Hg) at 15^(@)C . Calculate the molecular mass of the polymer.

One liter aqueous solutions contains 2 xx 10^(-2) kg glucose at 25^@C . Calculate the osmotic pressure of the solution.

The density of a gas is found to be 1.56 g dm^(-3) at 0.98 bar pressure and 65^(@)C . Calculate the molar mass of the gas.

The mass of 0.5 dm^(3) of hydrogen at a pressure of 1 bar of Hg and at a temperature of 300 K was found to be 4.0 xx 10^(-2) g . Calculate the molar mass of hydrogen.