An aqueous solution of a protein has an osomatic pressure of 3.8 mm of Hg at temperature of `300K` . If concentration of protein is `(1)/(49.26) %` w/v , then calculate molecular mass of protein.

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 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.

200 mL of a very dilute aqueous solution of a protein contains 1.9 gm of the protein . If osmotic rise of such a solution at 300K is found to be 38 mm of solution then calculate molar mass of the protein . (Take R = 0.008 L atm mol^(-1) K^(-1) )

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

Osmotic pressure of a solution contaning 7 g.of a protein per 100 cm^(3) of solution is 3.3 xx 10^(-2) atm at 37^(@)C . Calculate the molar mass of protein.

If 250 cm^3 of an aqueous solution containing 0.73 g of a protein A of isotonic with one litre of another aqueous solution containing 1.65 g of a protein B, at 298 K, the ratio of the molecular masses of A and B is ________ xx 10^(-2) ( to the nearest integer).