A solution cantains 0.8960 g of `K_(2)SO_(4)` in 500 mL. Its osmotic pressure is found to be 0.69 atm at `27^(@)C`. Calculate the value of Van't Hoff factor.

A solution contains 0.8133 g of K_(2)SO_(4) in 500 mL . If osmotic pressure is found to be 0.69 atm at 27^(circ)C . Calculate the value of van't Hoff's factor.

A solution contins 0 .860 g of K_(2)SO_(4) in 500 mL solution . Its osmotic pressure is found to be 0.690 atm at 27^(@)C . Calculate the value of Van't Hoff factor . (At mass K = 39.0 , S = 32, O = 16 R = 0.082 atm mol^(-1) K^(-1) )

Osmotic pressure of a 0.01 M solution is 0.7 atm at 27^(@)C , its van't Hoff factor will be

The osmotic pressure of a solution containing 5 g of substance (molar mass =100) in 308 m L of solution was found to be 4.0 atm at 300 K . Calculate the value of solution constant (R)

STATEMENT-1 : 0.1 M solution of Na_(2)SO_(4) has greater osmotic pressure than 0.1 M solution of urea at same temperature. and STATEMENT-2 : The value of van't Hoff factor for Na_(2)SO_(4) is less than urea.

Calculate the freezing point depression expected for 0.0711 m aqueous solution of Na_(2)SO_(4) . If this solution actually freezes at -0.320 ^(@)C , what would be the value of Van't Hoff factor ? ( K_(f) for water is 1.86 ^(@)C mol^(-1) ) .

A solution is prepared by dissolveing 26.3g of CdSO_(4) in 1000g water. The depression in freezing point of solution was found to be 0.284K. Calculate the Van't Hoff factor. The cryoscopic constant of water is 1.86K kg solvent "mol"^(-1)-"solute" .