Elevation in b.p of an aqueous urea solution is `0.52^(0). (K_(b)=0.52^(0)"mol"^(-1)kg`). Hence, mole -fraction of urea in this solution is :

The mole fraction of solvent in 0.1 molal aqueous solution is

The elevation in boling point of an aqueous solutions of NaCl is 0.01 .^(@) C . If its van't Hoff factor is 1.92 ,the molality of NaCl solution is ( K_(b) for water = 0 . 52 k kg mol^(-1) )

Mole fraction of the solute in a 1.00 molal aqueous solution is

A complex of iron and cyanide ions is 100% ionised at 1m (mol). If its elevation in b.p is 2.8^(0) , ( K_(b)=0.52^(0) "mol"^(-1)Kg ), then the complex is :

A complex of iron and cynanide ions is 100% ionised at 1m (molal) . If its elevation inb.p. is 208^(@), (K_(b)=0.52^(@)mol^(-1)Kg) , then the complex is :

Depression in freezing point of 0.01 molal aqueous HCOOH solution is 0.02046. one molal aqueous urea solution freezes at -1.86^(@)C , assuming molality equal to molari ty, pH of HCOOH solution is :

Mole fraction of water in aqueous sulphuric acid solution is 0.85. Calculate the molality.

2g of a non-electrolyte solute dissolved in 200 g of water shows an elevation of boiling point of 0.026^(@)C. K_(b) of water is 0.52 K . "mole"^(1) kg then the molecular weight of solute is x xx100 . What is the value of 'x'?