162.
A solution containing $$12.5\,g$$ of non-electrolyte substance in $$185\,g$$ of water shows boiling point elevation of $$0.80\,K.$$ Calculate the molar mass of the substance. $$\left( {{K_b} = 0.52\,K\,kg\,mo{l^{ - 1}}} \right)$$
Let the mass of methane and oxygen $${\text{ = }}m{\text{ }}gm.$$
Mole fraction of $${O_2}$$
$$\eqalign{
& = \frac{{{\text{Moles of}}\,{O_2}}}{{{\text{Moles of}}\,{O_2} + {\text{Moles of}}\,C{H_4}}} \cr
& = \frac{{\frac{m}{{32}}}}{{\frac{m}{{32}} + \frac{m}{{16}}}} \cr
& = \frac{{\frac{m}{{32}}}}{{\frac{{3m}}{{32}}}} \cr
& = \frac{1}{3} \cr} $$
Partial pressure of $${O_2} = $$ Total pressure $$ \times $$ mole fraction of $${O_2},\,{P_{{O_2}}} = P \times \frac{1}{3} = \frac{1}{3}P$$
164.
Vapour pressure of a pure liquid $$X$$ is $$2\,atm$$ at $$300\,K.$$ It is lowered to $$1\,atm$$ on dissolving $$1\,g$$ of $$Y$$ in $$20\,g$$ of liquid $$X.$$ If molar mass of $$X$$ is $$200,$$ what is the molar mass of $$Y?$$
165.
The Tyndall effect is observed only when following
conditions are satisfied :
(i) The diameter of the dispersed particles is much smaller than the wavelength of the light used.
(ii) The diameter of the dispersed particle is not much smaller than the wavelength of the light used.
(iii) The refractive indices of the dispersed phase and dispersion medium are almost similar in magnitude.
(iv) The refractive indices of the dispersed phase and dispersion medium differ greatly in magnitude.
The Tyndall effect is observed only when following conditions are satisfied :
The diameter of the dispersed particles is much smaller than the wavelength of the light used.
The diameter of the dispersed particle is not much smaller than the wavelength of the light used.
The refractive indices of the dispersed phase and dispersion medium are almost similar in magnitude.
The refractive indices of the dispersed phase and dispersion medium differ greatly in magnitude.
166.
$$12\,g$$ of urea is dissolved in 1 litre of water and $$68.4\,g$$ of sucrose is dissolved in 1 litre of water. The lowering of vapour pressure of first case is
$$\eqalign{
& {\text{Moles of urea}} = \frac{{12}}{{60}} = 0.2 \cr
& {\text{Moles of sucrose}} = \frac{{68.4}}{{342}} = 0.2 \cr} $$
Both are non electrolyte hence lowering of $$V.P.$$ will be same.
167.
Formation of a solution from two components can be considered as
(i) pure solvent → separated solvent molecules, $$\Delta {H_1}$$
(ii) pure solute → separated solute molecules, $$\Delta {H_2}$$
(iii) separated solvent and solute molecules → solution, $$\Delta {H_3}$$
Solution so formed will be ideal, if
168.
Which of the following statements about the composition of the vapour over an ideal 1 : 1 $$molar$$ mixture of benzene and toluene is correct? Assume that the temperature is constant at $${25^ \circ }C.$$
( Given, vapour pressure data at $${25^ \circ }C,$$ benzene $$ = 12.8\,kPa,$$ toluene $$ = 3.85\,kPa$$ )
A
The vapour will contain a higher percentage of toluene
B
The vapour will contain equal amounts of benzene and toluene
C
Not enough information is given to make a prediction
D
The vapour will contain a higher percentage of benzene
Answer :
The vapour will contain a higher percentage of benzene
Since, component having higher vapour pressure will have higher percentage in vapour phase. Benzene has vapour pressure $$12.8$$ $$kPa$$ which is greater than toluene $$3.85$$ $$kPa.$$
Therefore, the vapour will contain a higher percentage of benzene.
169.
According to Raoult’s law, relative lowering of vapour pressure of a solution is equal to
According to Raoult’s law, the relative lowering of vapour pressure is equal to the mole fraction of solute, i.e.
$$\eqalign{
& \frac{{{p^ \circ } - p}}{{{p^ \circ }}} = {\chi _B} \cr
& {\chi _B} = {\text{mole fraction of solute}} \cr} $$
170.
What is the mole fraction of glucose in $$10\% \,\,w/W$$ glucose solution ?