Chapter 6, Problem 6E.4E

(a)

Interpretation Introduction

Interpretation:

The $pHof0.10M{H}_{2}S\left(aq\right)$ has to be calculated.

Explanation of Solution

$H_{2}S$ is a polyprotic acid.  The first and second deprotonation reactions are given below.

  $\begin{array}{l}{H}_{2}S\left(aq\right)+H_{2}O\left(l\right)\rightleftharpoons H_3{O}^{+}\left(aq\right)+H{S}^{-}\left(aq\right),K_{a1}=1.3\times {10}^{-7}\\ \\ H{S}^{-}\left(aq\right)+H_{2}O\left(l\right)\rightleftharpoons H_3{O}^{+}\left(aq\right)+S^{2-}\left(aq\right),K_{a2}=7.1\times {10}^{-15}\end{array}$

The second deprotonation can be ignored.

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

  $K_{a1}=\frac{\left[H_3{O}^{+}\right]\left[H{S}^{-}\right]}{\left[H_{2}S\right]}$

An equilibrium table can be set up as given below.

  $\begin{array}{ccccc}Composition\left(M\right)& H_{2}S& H_{2}O& H_3{O}^{+}& H{S}^{-}\\ Initialconcentration& 0.10& -& 0& 0\\ Changeinconcentration& -x& -& +x& +x\\ Equilibriumconcentration& 0.10-x& -& x& x\end{array}$

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

  $K_{a1}=\frac{\left(x\right)\left(x\right)}{\left(0.10-x\right)}$

Now, the above expression can be solved for x.

  $\begin{array}{l}{K}_{a1}=\frac{\left(x\right)\left(x\right)}{\left(0.10-x\right)}\\ \\ 1.3\times {10}^{-7}=\frac{\left(x\right)\left(x\right)}{\left(0.10-x\right)}\\ \\ \left(1.3\times {10}^{-7}\right)\left(0.10-x\right)=x^2\\ \\ x^2+1.3\times {10}^{-7}x-1.3\times {10}^{-8}=0\\ \\ x=\frac{\left(-1.3\times {10}^{-7}\right)\pm \sqrt{{\left(1.3\times {10}^{-7}\right)}^2-\left(4\right)\times \left(1\right)\times \left(-1.3\times {10}^{-8}\right)}}{2}\\ \\ x=1.14\times {10}^{-4}\\ \\ \left[H_3{O}^{+}\right]=x=1.14\times 10^{-4}\end{array}$

The $pH$ of the solution can now be calculated.

  $pH=-\log \left[H_3{O}^{+}\right]=-\log \left(1.14\times {10}^{-4}\right)=3.94$

Therefore, $pHof0.10M{H}_{2}S\left(aq\right)$ is $3.94.$

(b)

Interpretation Introduction

Interpretation:

The $pHof0.15M{H}_2{C}_4{H}_4{O}_6\left(aq\right)$ has to be calculated.

Explanation of Solution

$H_2{C}_4{H}_4{O}_6$ is a polyprotic acid.  The first and second deprotonation reactions are given below.

  $\begin{array}{l}{H}_2{C}_4{H}_4{O}_6\left(aq\right)+H_{2}O\left(l\right)\rightleftharpoons H_3{O}^{+}\left(aq\right)+H{C}_4{H}_4{O}_6{}^{-}\left(aq\right),K_{a1}=6.0\times {10}^{-4}\\ \\ H{C}_4{H}_4{O}_6{}^{-}\left(aq\right)+H_{2}O\left(l\right)\rightleftharpoons H_3{O}^{+}\left(aq\right)+C_4{H}_4{O}_6{}^{2-}\left(aq\right),K_{a2}=1.5\times {10}^{-5}\end{array}$

The second deprotonation can be ignored.

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

  $K_{a1}=\frac{\left[H_3{O}^{+}\right]\left[H{C}_4{H}_4{O}_6{}^{-}\right]}{\left[H_2{C}_4{H}_4{O}_6\right]}$

An equilibrium table can be set up as given below.

  $\begin{array}{ccccc}Composition\left(M\right)& H_2{C}_4{H}_4{O}_6& H_{2}O& H_3{O}^{+}& H{C}_4{H}_4{O}_6{}^{-}\\ Initialconcentration& 0.15& -& 0& 0\\ Changeinconcentration& -x& -& +x& +x\\ Equilibriumconcentration& 0.15-x& -& x& x\end{array}$

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

  $K_{a1}=\frac{\left(x\right)\left(x\right)}{\left(0.15-x\right)}$

Now, the above expression can be solved for x.

  $\begin{array}{l}{K}_{a1}=\frac{\left(x\right)\left(x\right)}{\left(0.15-x\right)}\\ \\ 6.0\times {10}^{-4}=\frac{\left(x\right)\left(x\right)}{\left(0.15-x\right)}\\ \\ \left(6.0\times {10}^{-4}\right)\left(0.15-x\right)=x^2\\ \\ x^2+6.0\times {10}^{-4}x-9\times {10}^{-5}=0\\ \\ x=\frac{\left(-6.0\times {10}^{-4}\right)\pm \sqrt{{\left(6.0\times {10}^{-4}\right)}^2-\left(4\right)\times \left(1\right)\times \left(-9\times {10}^{-5}\right)}}{2}\\ \\ x=9.2\times {10}^{-3}\\ \\ \left[H_3{O}^{+}\right]=x=9.2\times 10^{-3}\end{array}$

The $pH$ of the solution can now be calculated.

  $pH=-\log \left[H_3{O}^{+}\right]=-\log \left(9.2\times {10}^{-3}\right)=2.03$

Therefore, $pHof0.15M{H}_2{C}_4{H}_4{O}_6\left(aq\right)$ is $2.03.$

(c)

Interpretation Introduction

Interpretation:

The $pHof1.1\times {10}^{-3}M{H}_{2}Te{O}_4\left(aq\right)$ has to be calculated.

Explanation of Solution

$H_{2}Te{O}_4$ is a polyprotic acid.  The first and second deprotonation reactions are given below.

  $\begin{array}{l}{H}_{2}Te{O}_4\left(aq\right)+H_{2}O\left(l\right)\rightleftharpoons H_3{O}^{+}\left(aq\right)+HTe{O}_4{}^{-}\left(aq\right),K_{a1}=2.1\times {10}^{-8}\\ \\ HTe{O}_4{}^{-}\left(aq\right)+H_{2}O\left(l\right)\rightleftharpoons H_3{O}^{+}\left(aq\right)+Te{O}_4{}^{2-}\left(aq\right),K_{a2}=6.5\times {10}^{-12}\end{array}$

The second deprotonation can be ignored.

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

  $K_{a1}=\frac{\left[H_3{O}^{+}\right]\left[HTe{O}_4{}^{-}\right]}{\left[H_{2}Te{O}_4\right]}$

An equilibrium table can be set up as given below.

  $\begin{array}{ccccc}Composition\left(M\right)& H_{2}Te{O}_4& H_{2}O& H_3{O}^{+}& HTe{O}_4{}^{-}\\ Initialconcentration& 1.1\times {10}^{-3}& -& 0& 0\\ Changeinconcentration& -x& -& +x& +x\\ Equilibriumconcentration& 1.1\times {10}^{-3}-x& -& x& x\end{array}$

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

  $K_{a1}=\frac{\left(x\right)\left(x\right)}{\left(1.1\times {10}^{-3}-x\right)}$

Now, the above expression can be solved for x.

  $\begin{array}{l}{K}_{a1}=\frac{\left(x\right)\left(x\right)}{\left(1.1\times {10}^{-3}-x\right)}\\ \\ 2.1\times {10}^{-8}=\frac{\left(x\right)\left(x\right)}{\left(1.1\times {10}^{-3}-x\right)}\\ \\ \left(2.1\times {10}^{-8}\right)\left(1.1\times {10}^{-3}-x\right)=x^2\\ \\ x^2+2.1\times {10}^{-8}x-2.31\times {10}^{-11}=0\\ \\ x=\frac{\left(-2.1\times {10}^{-8}\right)\pm \sqrt{{\left(2.1\times {10}^{-8}\right)}^2-\left(4\right)\times \left(1\right)\times \left(-2.31\times {10}^{-11}\right)}}{2}\\ \\ x=4.79\times {10}^{-6}\\ \\ \left[H_3{O}^{+}\right]=x=4.79\times 10^{-6}\end{array}$

The $pH$ of the solution can now be calculated.

  $pH=-\log \left[H_3{O}^{+}\right]=-\log \left(\text{4}{\text{.79×10}}^{\text{-6}}\right)=5.32$

Therefore, $pHof1.1\times {10}^{-3}M{H}_{2}Te{O}_4\left(aq\right)$ is $5.32.$