Chloroform , `CHCl_(3)`, boils at `61.7^(@)`C. If the `K_(b)` for choroform is `3.63^(@)C//"molal"`, what is the boiling point of a solution of 15.0 kg of` CHCl_(3)` and 0.616 kg of acenaphthalene, `C_(12)H_(10)` ?

What is the boiling point of water H_2O at 0^(@) - State (A) H_2O at 100^(@) - State (B) H_2O at 80^(@) - State (C)

Which of the following compounds are covalent ? A) H_2 b) Cao c) CHCl_3 d) BI_3

Boiling point of 100 g water containing 12 g of glucose dissolved in 100.34^@C . What is K_b of water ?

1.0 molal aqueous solution of an electrolyte X_(3)Y_(2) is 25% ionized. The Boiling point of the solution is (K_(b) of H_(2)O=0.52K kg mol^(-1))

A solution of urea has boiling point 100.15^@C, K_f and K_b for water are 1.87 and 0.52 K kg "mol"^(-1) . Calculate (a) molality and (b) freezing point of the solution.

An aqueous solution freezes at - 0.372^@C . If K_f and K_b for water are 1.86K kg "mol"^(-1) and 0.53 K kg "mol"^(-1) respectively, the elevation in boiling point of same solution in K is:

Boiling point of water 750 mm Hg is 99.63^(@)C . How much sucrose is to be added to 500 g of water such that it boils at 100^(@)C . [K_(b) for water is 0.52" K kg mol"^(-1)] i) Since boiling point is changing, apply the formula for elevation in boiling point, Delta"T"_(b)=K_(b)m ii) m=(W_(B))/(M_(B).W_(A)) So, DeltaT_(b)=(K_(b).W_(B))/(M_(B)xxW_(A)) Or W_(B)=(DeltaT_(b)xxM_(B)xxW_(A))/(K_(b)) iii) Find DeltaT_(b)" as "DeltaT_(b)=T_(b)=T_(b)-T_(b)^(0) T_(b) = Boiling point of solution T_(b)^(0) = Boiling point of pure solvent

At 100^@ C the vapour pressure of a solution of 6.5 gm of a solute in 100 gm of water is 732 mm. If K_b = 0.52, the boiling point of this solution will be