Consider the following half cell reaction $ \text{Cr}_2\text{O}_7^{2-} (\text{aq}) + 6\text{e}^- + 14\text{H}^+ (\text{aq}) \longrightarrow 2\text{Cr}^{3+} (\text{aq}) + 7\text{H}_2\text{O}(1) $
The reaction was conducted with the ratio of $\frac{[\text{Cr}^{3+}]^2}{[\text{Cr}_2\text{O}_7^{2-}]} = 10^{-6}$
The pH value at which the EMF of the half cell will become zero is ____ (nearest integer value)
[Given : standard half cell reduction potential $\text{E}^\circ_{\text{Cr}_2\text{O}_7^{2-}, \text{H}^+/\text{Cr}^{3+}} = 1.33\text{V}, \quad \frac{2.303\text{RT}}{\text{F}} = 0.059\text{V}$
To determine the pH at which the half-cell's EMF is zero, the Nernst equation is applied to the reaction:
\( \text{Cr}_2\text{O}_7^{2-} + 6\text{e}^- + 14\text{H}^+ \rightarrow 2\text{Cr}^{3+} + 7\text{H}_2\text{O} \)
The Nernst equation is:
\( E = E^\circ - \frac{0.059}{n} \log Q \)
Where \( E \) is the EMF, \( E^\circ \) is the standard reduction potential (1.33 V), \( n \) is the number of electrons transferred (6), and \( Q \) is the reaction quotient:
\( Q = \frac{[\text{Cr}^{3+}]^2}{[\text{Cr}_2\text{O}_7^{2-}][\text{H}^+]^{14}} \)
Given that \( \frac{[\text{Cr}^{3+}]^2}{[\text{Cr}_2\text{O}_7^{2-}]} = 10^{-6} \), then \( Q = 10^{-6}[\text{H}^+]^{-14} \).
Setting the EMF to zero:
\( 0 = 1.33 - \frac{0.059}{6} \log \left(10^{-6}[\text{H}^+]^{-14} \right) \)
Solving for pH:
\( \frac{0.059}{6} \log \left(10^{-6}[\text{H}^+]^{-14} \right) = 1.33 \)
\( \log \left(10^{-6}[\text{H}^+]^{-14} \right) = 135.59 \)
Expanding the logarithm:
\( \log 10^{-6} + \log [\text{H}^+]^{-14} = 135.59 \)
\( -6 - 14\log [\text{H}^+] = 135.59 \)
Calculating \(\log [\text{H}^+]\):
\( -14\log [\text{H}^+] = 141.59 \)
\( \log [\text{H}^+] = -10.11 \)
The pH is calculated as:
\( \text{pH} = -\log [\text{H}^+] = 10.11 \)
The closest integer to the calculated pH is \( \mathbf{10} \), which is consistent with the provided range (10, 10).