Chapter 5, Problem 5I.13E

(a)

Interpretation Introduction

Interpretation:

The equilibrium composition of the mixture in a reaction vessel of volume $2.00L$ has to be calculated.  The reaction is given below.

  $C{l}_2\left(g\right)\rightleftharpoons 2Cl\left(g\right),K_c=1.2\times {10}^{-7}$

Explanation of Solution

The required reaction is given below.

  $C{l}_2\left(g\right)\rightleftharpoons 2Cl\left(g\right),K_c=1.2\times {10}^{-7}$

The expression for equilibrium constant for the above reaction can be written as shown below,

  $K_c=\frac{{\left[Cl\right]}^2}{\left[C{l}_2\right]}$

Given that, $2.0mmolC{l}_2\left(g\right)$ was sealed into a reaction vessel of volume $2.0L.$  The concentration of $C{l}_2\left(g\right)$ can be calculated as given below.

  $\left[C{l}_2\right]=\frac{moles}{volume}=\frac{2\times {10}^{-3}mol}{2.00L}=0.001M$

An equilibrium table can be set up as given below.

  $\begin{array}{ccc}Composition(M)& C{l}_2& Cl\\ Initialconcentration& 0.001& 0\\ Changeinconcentration& -x& +2x\\ Equilibriumconcentration& 0.001-x& 2x\end{array}$

Now, these values in the fourth row can be inserted in the equilibrium constant expression as shown below.

  $K_c=\frac{{\left(2x\right)}^2}{\left(0.001-x\right)}$

By assuming $x\ll 0.001$, it can be written that $0.001-x\simeq \mathrm{0.001.}$

Now, the above equilibrium expression can be solved for $x.$

  $\begin{array}{l}{K}_c=\frac{{\left(2x\right)}^2}{\left(0.001-x\right)}\\ \\ 1.2\times {10}^{-7}=\frac{4x^2}{\left(0.001\right)}\\ \\ x^2=\frac{1.2\times {10}^{-7}\times {10}^{-3}}{4}\\ \\ x=5.5\times 10^{-6}\\ \\ \left[C{l}_2\right]=0.001M\\ \\ \left[Cl\right]=2x=2\times \text{5}{\text{.5×10}}^{\text{-6}}=1.1\times 10^{-5}M\end{array}$

Therefore, the equilibrium concentrations of $C{l}_{2}andCl$ in a reaction vessel are $0.001Mand1.1\times 10^{-5}M$ respectively.

(b)

Interpretation Introduction

Interpretation:

The equilibrium composition of the mixture in a reaction vessel of volume $2.00L$ has to be calculated.  The reaction is given below.

  $F_2\left(g\right)\rightleftharpoons 2F\left(g\right),K_c=1.2\times {10}^{-4}$

Explanation of Solution

The required reaction is given below.

  $F_2\left(g\right)\rightleftharpoons 2F\left(g\right),K_c=1.2\times {10}^{-4}$

The expression for equilibrium constant for the above reaction can be written as shown below,

  $K_c=\frac{{\left[F\right]}^2}{\left[F_2\right]}$

Given that, $2.0mmol{F}_2\left(g\right)$ was sealed into a reaction vessel of volume $2.0L.$  The concentration of $F_2\left(g\right)$ can be calculated as given below.

  $\left[F_2\right]=\frac{moles}{volume}=\frac{2\times {10}^{-3}mol}{2.00L}=0.001M$

An equilibrium table can be set up as given below.

  $\begin{array}{ccc}Composition(M)& F_2& F\\ Initialconcentration& 0.001& 0\\ Changeinconcentration& -x& +2x\\ Equilibriumconcentration& 0.001-x& 2x\end{array}$

Now, these values in the fourth row can be inserted in the equilibrium constant expression as shown below.

  $K_c=\frac{{\left(2x\right)}^2}{\left(0.001-x\right)}$

By assuming $x\ll 0.001$, it can be written that $0.001-x\simeq \mathrm{0.001.}$

Now, the above equilibrium expression can be solved for $x.$

  $\begin{array}{l}{K}_c=\frac{{\left(2x\right)}^2}{\left(0.001-x\right)}\\ \\ 1.2\times {10}^{-4}=\frac{4x^2}{\left(0.001\right)}\\ \\ x^2=\frac{1.2\times {10}^{-4}\times {10}^{-3}}{4}\\ \\ x=5.5\times 10^{-8}\\ \\ \left[F_2\right]=0.001M\\ \\ \left[F\right]=2x=2\times \text{5}{\text{.5×10}}^{\text{-8}}=1.1\times 10^{-7}M\end{array}$

Therefore, the equilibrium concentrations of $F_{2}andF$ in a reaction vessel are $0.001Mand1.1\times 10^{-7}M$ respectively.

(c)

Interpretation Introduction

Interpretation:

The one which is thermodynamically more stable relative to its atoms at $1000K$ has to be determined.

Explanation of Solution

Then dissociation constant of $F_2$ is larger than that of $C{l}_2$ at $1000K.$  This infers that at $1000K$ more $F_2$ will dissociate to its atoms than that of $C{l}_2.$  Therefore, $C{l}_2$ is more stable relative to its atoms at $1000K.$