Nernst Equation


Electrochemical context

The Nernst equation links electrode potential to concentration/activity ratios. It enables realistic cell-voltage analysis beyond standard-state conditions.

\[ E = E^\circ - \frac{RT}{nF}\ln Q \]

It is fundamental for galvanic cells, electrochemical sensors, corrosion analysis, and redox system modeling.

  • Concentration and temperature impact on voltage
  • Back-calculation of reaction quotient from measured potential
  • Comparison of standard vs operating conditions
Context page with explicit cell-voltage focus: Cell Voltage (Non-Standard)
Formulas (MathJax)
\[ E = E^\circ - \frac{RT}{nF}\ln Q \]
\[ \ln Q = \frac{(E^\circ-E)nF}{RT},\qquad Q=\exp\left(\frac{(E^\circ-E)nF}{RT}\right) \]
\[ E_{\mathrm{cell}} = E_{\mathrm{cathode}} - E_{\mathrm{anode}} \]
\[ E_{\mathrm{cell}} = \left(E^\circ_{\mathrm{C}} - \frac{RT}{n_{\mathrm{C}}F}\ln Q_{\mathrm{C}}\right) - \left(E^\circ_{\mathrm{A}} - \frac{RT}{n_{\mathrm{A}}F}\ln Q_{\mathrm{A}}\right) \]
\[ E_{298\,K}=E^\circ-\frac{0.025693}{n}\ln Q \]
Symbol legend
  • \(E\): electrode potential under operating conditions [V]
  • \(E^\circ\): standard electrode potential [V]
  • \(E_{\mathrm{cell}}\): cell voltage [V]
  • \(E_{\mathrm{cathode}}, E_{\mathrm{anode}}\): half-cell potentials [V]
  • \(R\): gas constant \(8.314\,\mathrm{J\,mol^{-1}\,K^{-1}}\)
  • \(T\): absolute temperature [K]
  • \(n\): number of transferred electrons
  • \(F\): Faraday constant \(96485\,\mathrm{C\,mol^{-1}}\)
  • \(Q\): reaction quotient (activity/concentration form)


Detailed examples
Example 1:
\(E^\circ=1.10\,V\), \(n=2\), \(T=298.15\,K\), \(Q=10\)
\(E\approx1.070\,V\)
Example 2:
Same system, but \(Q=100\)
Potential decreases further because \(\ln Q\) grows.
Example 3:
Given \(E=1.07\,V\), \(E^\circ=1.10\,V\)
Back-calculation yields \(Q\approx 10\) for \(n=2\), \(T=298\,K\).
Example 4 (Zn/Cu galvanic cell):
\(E^\circ_{\mathrm{C}}=0.34\,V\), \(E^\circ_{\mathrm{A}}=-0.76\,V\), \(Q_C=Q_A=1\)
\(E_{\mathrm{cell}}\approx1.10\,V\)
Practical note:
For high-precision work, activities should replace pure concentrations, especially at higher ionic strengths.
Deeper insight
Temperature effect on E

As temperature increases, \(RT/(nF)\) increases, so the concentration term has a stronger influence on potential.

Practical applications

The Nernst equation is used in battery diagnostics, potentiometric sensing, corrosion engineering, and electrochemical analytics for consistent interpretation of measured voltages.

Is this page helpful?            
Thank you for your feedback!

Sorry about that

How can we improve it?