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Question: Calculate the boiling point of solution when 4g of \(MgS{O_4}\left( {M = 120gmo{l^ - }} \right)\) wa...

Calculate the boiling point of solution when 4g of MgSO4(M=120gmol)MgS{O_4}\left( {M = 120gmo{l^ - }} \right) was dissolved in 100g of water, assuming MgSO4MgS{O_4} undergoes complete ionization.
[Kbfor water = 0.52kgmol1]\left[ {{K_b}\,\,{\text{for water = 0}}{\text{.52}}kgmo{l^{ - 1}}} \right]

Explanation

Solution

Hint- To solve this question, we will use the concept of elevation of boiling point. As we know that when a small amount of solute is added to the solvent, the boiling point of the solution increases and the elevation in the boiling point is directly proportional to the concentration of the solute in the solution. So we will begin with calculating the molality of the solute in the solution and then proceed accordingly.

Complete step by step solution:
Formula used- The elevation in boiling point is given by
ΔTb=i×Kb×m\Delta {T_b} = i \times {K_b} \times m
Where
ΔTb\Delta {T_b} is the elevation in the boiling point
ii is the van't Hoff factor
Kb{K_b} is ebullioscopic constant
m is the molality of the solute
Given
Mass of MgSO4MgS{O_4} = 4g
Molar mass of MgSO4MgS{O_4} = 120gmol1120gmo{l^{ - 1}}
Mass of water = 100g = 0.1kg
The number of moles of the MgSO4MgS{O_4}
moles=massofsolutemolarmassofsolute moles=4g120gmol1 moles=0.0333mol moles = \dfrac{{mass\,\,of\,\,solute}}{{molar\,mass\,of\,solute}} \\\ moles = \dfrac{{4g}}{{120gmo{l^{ - 1}}}} \\\ moles = 0.0333mol \\\
Now we will calculate the molality of the solute Which is given by
molality=moles of MgSO4 mass of water in kgmolality = \dfrac{{{\text{moles of MgS}}{{\text{O}}_4}}}{{{\text{ mass of water in kg}}}}
Substituting the values of the moles of solute and mass of water
molality=moles of MgSO4 mass of water in kg3 molality=0.0333mol 0.1kg molality=0.333m molality = \dfrac{{{\text{moles of MgS}}{{\text{O}}_4}}}{{{\text{ mass of water in kg}}}}3 \\\ molality = \dfrac{{0.0333mol}}{{{\text{ 0}}{\text{.1kg}}}} \\\ molality = 0.333m \\\
To calculate the van't Hoff factor is calculated as when on electrolysis the number of ions produced in the solution is equal to the van't Hoff factor
Therefore
MgSO4Mg2++SO42MgS{O_4}\xrightarrow{{}}M{g^{2 + }} + SO_4^{2 - }
The molecule dissociate into two ions, therefore i = 2
Now we will calculate the elevation in the boiling point using the formula
ΔTb=i×Kb×m\Delta {T_b} = i \times {K_b} \times m
Substituting the value of the above quantities
ΔTb=i×Kb×m ΔTb=2×0.52×0.333 ΔTb=0.3466K  \Delta {T_b} = i \times {K_b} \times m \\\ \Delta {T_b} = 2 \times 0.52 \times 0.333 \\\ \Delta {T_b} = 0.3466K \\\
The normal boiling point of the water at room temperature is 100 degree Celsius or 373.15K
Due to addition of the solute the increase in the boiling point of water is
= 373.15 + 0.3466 \\\ = 373.5K \\\

The new boiling point of the solution is 373.5K

Note- In order to solve these types of questions, you need to have a good concept of solute, solvent and solution. Also the boiling point is the temperature at which vapour pressure is equal to the atmospheric pressure or surrounding pressure. With the addition of solute the boiling point of the solution increases because the greater amount of heat is needed to boil the solution. In the above question we calculated the concentration of the solute in the solution and then using the formula of elevation calculated the increase in temperature.