The amount of urea to be dissolved in 500 c.c. of water `(K_(f) H_(2)O = 1.86K mol^(-1)kg)` to produce a depression of `0.186^(@)C` in the freezing point is :

The amount of urea to be dissolved in 500 cc of water (K_(f)=1.86) to produce a depresssion of 0.186^(@)C in the freezing point is :

The cryoscopic contant of water is 1.86 K kg mol^(-1) . A 0.01 molal acetic acid solution produces a depression of 0.0194^(@)C in the freezing point. The degree of dissociation of acetic acid is :

How many grams of sucrose (molecular weight 342) should be dissolved in 100 g water in order to produce a solution with 105^(@)C difference between the freezing point and the boiling point ? (K_(b) =0.51^(@)C m^(-1) , (K_(f) =1.86^(@)C m^(-1))

How many moles of sucrose should be dissolved in 500gms of water so as to get a solution which has a difference of 104^(@)C between boiling point and freezing point. (K_(f)=1.86 K Kg "mol"^(-1).K_(b)=0.52K Kg "mol"^(-1))

The freezing point of a solution that contains 10 g urea in 100 g water is ( K_1 for H_2O = 1.86°C m ^(-1) )

Mole fraction of a non-electrolyte in aqueous solution is 0.07 . If K_(f) is 1.86^(@) "mol"^(-1)kg , depression if f.p.,DeltaT_(f), is:

When 20g of naphtholic acid (C_(11)H_(8)O_(2)) is dissolved in 50g of benzene (K_(f) = 1.72 K kg mol^(-1)) a freezing point depression of 2K is observed. The van'f Hoff factor (i) is

When 20 g of naphthoic acid (C_(11)H_(8)O_(2)) is dissolved in 50 g of benzene (K_(f)=1.72 K kg mol^(-1)) , a freezing point depression of 2 K is observed. The Van't Hoff factor (i) is

Depression in f.p. of an aqueous urea solutio is 1.86^(@) .(K_(f)=1.86^(@) mol^(-1) kg) Hence, mole - fraction of urea in this soluiton is :

The freezing point of a 1.00 m aqueous solution of HF is found to be -1.91^(@)C . The freezing point constant of water, K_(f) , is 1.86 K kg mol^(-1) . The percentage dissociation of HF at this concentration is:-