Answer
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Hint:
Degree of dissociation is the fraction of original solute molecules that have dissociated. It is usually indicated by Greek symbol $\alpha $.The formula of degree of dissociation is=$\dfrac{i-1}{n-1}$
Step by step solution of answer:
- We have been provided with following values-
Weight of solvent=1000g, here we need to convert it into kg. So, it is equal to 1kg.
Mass of $BaC{{l}_{2}}$added =12.48g
- Now, we need to calculate the molar mass of $BaC{{l}_{2}}$=
\[\begin{align}
& 137\times 2\left( 35.5 \right) \\
& =208.34g/mol \\
\end{align}\]
\[\Delta {{T}_{b}}=i\times {{K}_{b}}\times \dfrac{\text{mass of element}}{\text{molar mass of element}}\]
Where, i= vant hoff factor, ${{K}_{b}}$=boiling point constant
Also,$\Delta {{T}_{b}}={{T}_{f}}-{{T}_{f}}^{\circ }$
- Where, ${{T}_{f}}$= Final temperature and $T_{f}^{\circ }$= Initial temperature
- Firstly, we will calculate van't hoff factor which is equal to,
\[\begin{align}
& {{T}_{f}}-{{T}_{f}}^{\circ }=i\times {{K}_{b}}\times m \\
& \left( 373.0832-373 \right)=i\times 0.52\times \dfrac{12.4}{208.34\times 1} \\
\end{align}\]
The thing here to be noted is that temperature must be converted into Kelvin.
By solving above equation we get the value of, i=2.77
- Van't hoff factor is related to degree of dissociation as:
\[\alpha =\dfrac{i-1}{n-1}\]
\[\begin{align}
& \alpha =\dfrac{2.77-1}{3-1} \\
& \alpha =0.885 \\
\end{align}\]
Hence, we can conclude that the degree of dissociation of$BaC{{l}_{2}}$ is 0.885.
Additional information:
Degree of dissociation depends on all below factors-
- Nature of electrolyte- weak and strong, and concentration of electrolyte. And usually decreases with increase in concentration.
- As temperature increases, the degree of dissociation increases.
- The nature of solvent polar or non-polar also affects the degree of dissociation.
Note:
- Always remember that while solving this type of question it is mandatory to convert the temperature given in Celsius into Kelvin.
- As the common ion effect decreases then the degree of dissociation increases.
\[\Delta {{T}_{b}}=i\times {{K}_{b}}\times \dfrac{\text{mass of element}}{\text{molar mass of element}}\]
Common ion effect is the difference in equilibrium concentrations between a solution containing a common ion and the same solution in pure water. A common ion is present both in a salt added to a solution and in the solution itself.
Degree of dissociation is the fraction of original solute molecules that have dissociated. It is usually indicated by Greek symbol $\alpha $.The formula of degree of dissociation is=$\dfrac{i-1}{n-1}$
Step by step solution of answer:
- We have been provided with following values-
Weight of solvent=1000g, here we need to convert it into kg. So, it is equal to 1kg.
Mass of $BaC{{l}_{2}}$added =12.48g
- Now, we need to calculate the molar mass of $BaC{{l}_{2}}$=
\[\begin{align}
& 137\times 2\left( 35.5 \right) \\
& =208.34g/mol \\
\end{align}\]
\[\Delta {{T}_{b}}=i\times {{K}_{b}}\times \dfrac{\text{mass of element}}{\text{molar mass of element}}\]
Where, i= vant hoff factor, ${{K}_{b}}$=boiling point constant
Also,$\Delta {{T}_{b}}={{T}_{f}}-{{T}_{f}}^{\circ }$
- Where, ${{T}_{f}}$= Final temperature and $T_{f}^{\circ }$= Initial temperature
- Firstly, we will calculate van't hoff factor which is equal to,
\[\begin{align}
& {{T}_{f}}-{{T}_{f}}^{\circ }=i\times {{K}_{b}}\times m \\
& \left( 373.0832-373 \right)=i\times 0.52\times \dfrac{12.4}{208.34\times 1} \\
\end{align}\]
The thing here to be noted is that temperature must be converted into Kelvin.
By solving above equation we get the value of, i=2.77
- Van't hoff factor is related to degree of dissociation as:
\[\alpha =\dfrac{i-1}{n-1}\]
\[\begin{align}
& \alpha =\dfrac{2.77-1}{3-1} \\
& \alpha =0.885 \\
\end{align}\]
Hence, we can conclude that the degree of dissociation of$BaC{{l}_{2}}$ is 0.885.
Additional information:
Degree of dissociation depends on all below factors-
- Nature of electrolyte- weak and strong, and concentration of electrolyte. And usually decreases with increase in concentration.
- As temperature increases, the degree of dissociation increases.
- The nature of solvent polar or non-polar also affects the degree of dissociation.
Note:
- Always remember that while solving this type of question it is mandatory to convert the temperature given in Celsius into Kelvin.
- As the common ion effect decreases then the degree of dissociation increases.
\[\Delta {{T}_{b}}=i\times {{K}_{b}}\times \dfrac{\text{mass of element}}{\text{molar mass of element}}\]
Common ion effect is the difference in equilibrium concentrations between a solution containing a common ion and the same solution in pure water. A common ion is present both in a salt added to a solution and in the solution itself.
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