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Nernst Equation - Electrochemistry Video Lecture | Physical Chemistry

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FAQs on Nernst Equation - Electrochemistry Video Lecture - Physical Chemistry

1. What is the Nernst equation in electrochemistry?

Ans. The Nernst equation is a mathematical equation that relates the standard electrode potential, temperature, and concentration of ions to the cell potential of an electrochemical cell. It is given by E = E° - (RT/nF) * ln(Q), where E is the cell potential, E° is the standard electrode potential, R is the gas constant, T is the temperature in Kelvin, n is the number of moles of electrons transferred in the balanced equation, F is Faraday's constant, and Q is the reaction quotient.

2. How is the Nernst equation derived?

Ans. The Nernst equation is derived from the principles of thermodynamics and electrochemistry. It is based on the relationship between the free energy change of a reaction and the cell potential. By applying the principles of Gibbs free energy and the concept of equilibrium, the Nernst equation can be derived for electrochemical cells.

3. What is the significance of the Nernst equation in electrochemistry?

Ans. The Nernst equation is of great significance in electrochemistry as it allows us to determine the cell potential at non-standard conditions. It helps in understanding how changes in temperature and concentration affect the cell potential. By using the Nernst equation, we can calculate the potential of an electrochemical cell under any given conditions, which is crucial for various applications in fields such as batteries, corrosion, and fuel cells.

4. How does the Nernst equation relate to the pH of a solution?

Ans. The Nernst equation can be used to relate the pH of a solution to the cell potential of an electrochemical cell. In the case of a half-cell involving hydrogen ions, the Nernst equation can be written as E = E° - (0.0592/n) * log[H+], where [H+] represents the concentration of hydrogen ions. By measuring the cell potential and knowing the standard electrode potential, the pH of a solution can be determined using the Nernst equation.

5. Can the Nernst equation be used for all electrochemical cells?

Ans. The Nernst equation can be used for electrochemical cells involving reversible reactions. However, it may not be applicable for cells with irreversible reactions or when other factors such as resistance or current flow significantly affect the cell potential. In such cases, modifications to the Nernst equation or other equations may be required to accurately calculate the cell potential.

Text Transcript from Video

nonsti Gration
the equation which gives the
relationship between electric potential
and concentration of solution is called
Nernst equation for a general electrode
reaction MN plus atreus Plus and E minus
gives M solid this equation is given as
e MN plus by M equals to e naught MN
plus by M minus RT by NF Ln
concentration M solid by concentration
of atreus MN plus o II not MN plus by M
minus two point three not three RT by NF
log concentration M solid by
concentration of aqueous MN plus where e
MN plus by N equals two electrode
potential our gas constant inor MN plus
by him standard electrode potential T
stands for temperature n stands for
number of electrons gained during
electrode reaction f stands for Faraday
constant MN plus a q stands for
concentration of ions and that stands
for concentration of metal since the
concentration of solid phase is taken as
unity the Nernst equation becomes
electrode potential equals to standard
electrode potential minus two point
three not three RT by NF log one by a
concentration of ions for a redox
reaction and naught plus MN plus gives n
n plus M
the electrode potentials for the two
half-cells
are given as e n n plus by n equals to e
naught n n plus by n minus two point
three not three RT by n F log one by
concentration of aqueous NN + electrode
potential equals to standard electrode
potential minus two point three not
three RT by NF log one by a
concentration of ions

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	Nov 22, 2024 Last updated

Video Description: Nernst Equation - Electrochemistry for Chemistry 2024 is part of Physical Chemistry preparation. The notes and questions for Nernst Equation - Electrochemistry have been prepared according to the Chemistry exam syllabus. Information about Nernst Equation - Electrochemistry covers all important topics for Chemistry 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises and tests below for Nernst Equation - Electrochemistry.

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	Physical Chemistry 83 videos\|142 docs\|67 tests

Physical Chemistry

83 videos|142 docs|67 tests

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