At `100^(@)C` the vapour pressure of a solution of 6.5 g of a solute in 100 g water is 732 mm. If `K_(b)=0.52`, the boiling point of this solution will be

At 100^(@)C the vapour pressure of a solution of 6.5g of an solute in 100g water is 732mm .If K_(b)=0.52 , the boiling point of this solution will be :

The Vapour pressure of solution containing 2g of NaCl in 100g of water at 100^(@)C is 753.2mm of Hg , then degree of dissociation of NaCl .

The vapour pressure of pure benzene at 25^@C is 640.0 mm Hg and vapour pressure of a solution of a solute in benzene is 25^@C is 632.0 mm Hg. Find the freezing point of the solution if k_f for benzene is 5.12 K/m. (T_("benzene")^@ = 5.5^@C)

At 0^@C , the vapour pressure of pure water is 4.63 mm and an aqueous solution of 8.49 g of NaNO_3 dissolved in 100g of water is 4.483 mm. What is the extent of ionisation of NaNO_3 /

Calculate the vapour pressure of solution having 3.42g cane sugar in 180 g water at 40^(@)C and 100^(@)C . Given that boiling point of water is 100^(@)C and heat of vaporization is heat of vaporisation is 10 kcal/mol in the given temperature range. Also, calculate the lowering in vapour pressure of 0.2 molal cane solution at 40^(@)C .

An aqueous solution of a non-electrolyte boils at 100.52^@C . The freezing point of the solution will be

Calculate the boiling point of urea solution when 6 g of urea is dissolved in 200 g of water. ( K_(b) for water = 0·52 K kg mol^(-1) , boiling point of pure water = 373 K, mol.wt. of urea = 60)

Osmotic pressure of solution containing 0.6 g urea and 3.42 g sugar in 100 ml at 27^@C

At 48^(@)C , the vapour pressure of pure CS_(2) is 850torr . A solution of 2.0 g of sulphur in 100g of CS_(2) has a vapour pressure 844.9 torr. Determine the atomicity of sulphur molecule :