For a dilute solution containing 2.5 g o...

For a dilute solution containing `2.5 g` of a non-volatile non-electrolyte solution in `100g` of water, the elevation in boiling point at `1` atm pressure is `2^(@)C`. Assuming concentration of solute is much lower than the concentration of solvent, the vapour pressure (mm of `Hg)` of the solution is:
(take `k_(b) = 0.76 K kg mol^(-1))`

724

740

736

718

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`DeltaT_(f)=iK_(b)m` (`i=1` for non -electrolyte)`implies2.0.76xxn/(100/1000)impliesn=2/7.6`
Relative lowering in vapour pressure `=chi_(B)` (mole fraction of solute).
For dilute solution we can assume `(Deltap)/(PÅ)=(n_("solute"))/(n_("solvent"))`
`implies(DeltaP)/(p_(A)^(@))=(2//7.6)/(100//18)implies(DeltaP)/760=36/760impliesDelta=36impliesP=724`mm

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