The elevation in boiling point of a solution of `13.44 g` of `CuCl_(2)` in `1 kg` of water using the following information will be (molecular weight of `CuCl_(2)` is 134.4 and `K_(b)=0.52 K m^(-1))`

The elevation in boiling point of a solution of 13.44 g of CuCl_(2) (molecular weight = 134.4,k_(b)=0.52K "molality"^(-1)) in 1 kg water using the following information will be:

The elevation in boilng point of a solution of 13.44 g of CuCl_(2) 1 kg of water will be _____. (Molecular mass of CuCl_(2) = 134.4 and K_(b) =0.52 km^(-1))

The elevation in boiling point of a solution of 9.43 g of MgCl_2 in 1 kg of water is ( K_b = 0.52 K kg mol^(-1) , Molar mass of MgCl_2 = 94.3 g mol^(-1) )

If the elevation in boiling point of a solution of 10 g of solute (molecular weight = 100) in 100 g of water is Delta T_(b) , the ebullioscopic constant of water is

The boiling point of a solution made by dissolving 12.0 g of glucose in 100 g of water is 100.34^(@)C . Calculate the molecular weight of glucose, K_(b) for water = 0.52^(@)C//m .

Calculate the freezing point depression and boiling point elevation of a solution of 10.0 g of urea (M_(B)=60) in 50.0 g of water at 1 atm . pressure. K_(b) and K_(f) for water 0.52^(@)C m^(-1) and 1.86^(@)C m^(-1) respectively.

Elevation in boiling point of a solution of non-electrolyte in CCl_(4) is 0.60^(@)C . What is the depression in freezing point for the same solution? K_(f)(CCl_(4)) = 30.00 K kg mol^(-1), k_(b)(CCl_(4)) = 5.02 k kg mol^(-1)

The elevation in boiling point, when 13.44 g of freshly prepared CuCI_(2) are added to one kilogram of water, is [Some useful data, K_(b) (H_(2)O) = 0.52 kg K mol^(-1), "mol.wt of" CuCI_(2) = 134.4 gm]

Calculate elevation in boiling point for 2 molal aqueous solution of glucose. (Given K_b(H_(2)O) = 0.5 kg mol^(-1) )