A saturated solution of a salt MX exhibits an osmotic pressure of `74.4mm` Hg at `25^(@)C`. Assuming `100%` ionisation of MX, calculate `K_(SP)` of MX.

Calculate the osmotic pressure of 20% (wt. // vol.) anhydrous CaCl_(2) solution at 0^(@)C assuming 100% ionisation.

100 mg of a protein is dissolved in just enough water to make 10.0 mL of solution. If this solution has an osmotic pressure of 13.3mm Hg at 25^@C , what is the molar mass of the protein? (R = 0.0821L atm mol^-1 K^-1 and 760mm Hg = 1atm)

Solubility of Ca(OH)_2 in water is 1.5 kgm^(-3) at 25^@ C. Assuming 100% dissociation, calculate the pH of saturated solutions.

Calculate the osmotic pressure of 20% (wt. // vol.) anhydrous Ca(NO_(3))_(2) solution at 0^(@)C assuming 100% ionisation.

The solution having highest vapour pressure is :(Assume 100% ionisation of electrolytes)

Arrange the following solutions in order of increasing osmotic pressure. Assume 100% isonisation for electrolytes: {:(1N NaCl,1N Na_(2)SO_(4),IN Na_(3)PO_(4),,),(I,II,III,,):}

A solution of XY ( 100% ionised) has osmotic pressure equal to four times the osmotic pressure of 0.01 M BaCl_(2) ( 100% ionised). Find the molarity of XY

A solution of XY ( 100% ionised) has osmotic pressure equal to four times the osmotic pressure of 0.01 M BaCl_(2) ( 100% ionised). Find the molarity of XY