\[2F{{e}^{3+}}(aq)+2{{I}^{}}(aq)\to 2F{{e}^{2+}}(aq)+{{I}_{2}}(aq)\]\[E_{cell}^{\Theta }\text{ }E=0.24\text{ }Vat\text{ }298\text{ }K\]. The standard Gibbs energy \[({{\Delta }_{r}}{{G}^{\Theta }})\] of the cell reaction is: |
[Given that Faraday constant\[F=96500\text{ }C\text{ }mo{{l}^{1}}\]] |
A) \[46.32\text{ }kJ\text{ }mo{{l}^{1}}\]
B) \[23.16\text{ }kJ\text{ }mo{{l}^{1}}\]
C) \[-46.32\text{ }kJ\text{ }mo{{l}^{1}}\]
D) \[-23.16\text{ }kJ\text{ }mo{{l}^{1}}\]
Correct Answer: C
Solution :
\[\Delta G{}^\circ =-nF\,E_{cell}^{\Theta }\] \[=2(96500)\,\text{(}0.24\text{)}\] \[=-46320\text{ }J/mole\] \[=-\frac{46320}{1000}\] \[=-46.32\text{ }KJ/mole\]You need to login to perform this action.
You will be redirected in
3 sec