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

0.002 molar solutiion of NaCl having degree of dissociation of 90% at 27^(@)C has osmotic pressure equal to a.0.94 bar , b.9.4 bar , c.0.094 bar , d. 9.4xx10^(-4) bar

Two solutions of glucose have osmotic pressure 1.5 and 2.5 atm ,respectively. 1 L of first solution is mixed with 2 L of second solution. The osmotic pressure of the resultant solution will be a. 2.62 atm , b. 6.12 atm ,c. 3.26 atm , d. 2.16 atm

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 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

18 g glucose and 6 g urea are dissolved in 1 L aqueous solution at 27^(@)C . The osmotic pressure of the solution will be a. 8.826 atm , b. 4.926 atm ,c. 2.92 atm , d. 4.42 atm

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

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 5% aqueous solution of glucose (pi_(1)) is related to that of 5% aqueous solution of urea (pi_(2)) as