Class 12 Exam > Class 12 Videos > Additional Study Material for Class 12 > Cell Potential, Electrical Work & Free Energy
Cell Potential, Electrical Work & Free Energy Video Lecture | Additional Study Material for Class 12
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FAQs on Cell Potential, Electrical Work & Free Energy Video Lecture - Additional Study Material for Class 12
| 1. What is cell potential and how is it related to electrical work? |  |
Ans. Cell potential, also known as electromotive force (EMF), is the measure of the ability of a cell or battery to do work or produce an electric current. It is the driving force behind the flow of electrons in an electrochemical cell. Cell potential is directly related to electrical work as it determines the amount of energy that can be converted from chemical energy to electrical energy. The greater the cell potential, the more work can be done by the cell.
| 2. How is cell potential calculated? | |
Ans. Cell potential can be calculated using the Nernst equation. The Nernst equation is given by:
Ecell = E°cell - (RT/nF) * ln(Q)
Where:
- Ecell is the cell potential,
- E°cell is the standard cell potential,
- R is the gas constant (8.314 J/mol·K),
- T is the temperature in Kelvin,
- n is the number of moles of electrons transferred in the balanced equation,
- F is the Faraday constant (96,485 C/mol),
- Q is the reaction quotient.
By substituting the appropriate values into the equation, the cell potential can be determined.
| 3. What is the relationship between cell potential and free energy change? | |
Ans. The relationship between cell potential and free energy change is given by the equation:
ΔG = -nF Ecell
Where:
- ΔG is the change in Gibbs free energy,
- n is the number of moles of electrons transferred in the balanced equation,
- F is the Faraday constant (96,485 C/mol),
- Ecell is the cell potential.
This equation shows that the change in Gibbs free energy is directly proportional to the cell potential. A positive cell potential (Ecell) indicates a spontaneous reaction with a negative change in Gibbs free energy (ΔG), while a negative cell potential indicates a non-spontaneous reaction with a positive change in Gibbs free energy.
| 4. How does electrical work relate to the direction of electron flow in a cell? | |
Ans. The direction of electron flow in a cell is determined by the difference in electrical potential between the anode and cathode. If the cell potential is positive, indicating a higher potential at the cathode, electrons will flow from the anode to the cathode. This flow of electrons is what generates the electrical work in the cell. On the other hand, if the cell potential is negative, indicating a higher potential at the anode, the flow of electrons will be in the opposite direction.
| 5. What is the significance of cell potential and electrical work in practical applications? | |
Ans. Cell potential and electrical work have significant practical applications in various fields. They are used in the design and operation of batteries, fuel cells, and other electrochemical devices. Cell potential determines the voltage and energy output of these devices, which are essential for powering electronic devices, vehicles, and even large-scale energy storage systems. Understanding and manipulating cell potential and electrical work also play a crucial role in electroplating, corrosion prevention, and many chemical processes.
Text Transcript from Video
this is doctor Hayek and this video is
about electrochemistry today we will
talk about the relationship between the
cell potential electrical work and free
energy check my previous video on how to
calculate the standard cell reduction
potential I will post a link in the
description below today we will explore
the relationship between thermodynamics
and electrochemistry the work that can
be accomplished when electrons are
transferred through a wire depends on
the thermodynamic driving force this
driving force is defined in terms of
potential difference between two points
on the circuit and therefore the
electro-motive force is going to be
equal to the potential energy which is
equal to a Joule of work for a Coulomb
of charge
now here we'll consider the cell as the
system and since the work is done by the
cell it will be indicated by a negative
sign and therefore the potential energy
is going to be equal to minus W over Q
if we rearrange this expression we will
get that the work is equal to minus Q
multiplied by e max from this equation
it could be seen that the maximum work
that could be obtained at the maximum
cell potential and therefore W max is
equal to minus Q E max it's not worthy
to mention that we can never realize the
maximum work from a cell because of the
wasted energy through frictional heating
when a current flows however we can
measure the maximum cell potential using
an efficient digital voltmeter the
charge can be calculated by knowing the
amount of electrons or number of mole of
electrons passing through the wire and
using Faraday's constant and therefore Q
is equal to number of more electrons
multiplied by for a day's constant for
these law states that the charge of one
more electron is equal to ninety six
thousand four hundred eighty five
coulombs and therefore we have what we
call F which is the Faraday's constant
it's equal to 96 thousand four
hundred eighty-five coulombs per mole
electron and now we can relate the
potential of a galvanic cell to the free
energy we know that full process at
constant temperature and pressure the
change on free energy is equal to the
maximum of useful work and therefore
Delta G is equal to the work maximum and
we know that the work maximum is equal
to minus Q times the cell potential and
we know that Q is equal to number of
mole electrons multiplied by Faraday's
law so if we put all this together we
will have to the change of free energy
it's equal to minus number of mol
electrons multiplied by for a dis
constant multiplied by the maximum at
cell potential for standard conditions
Delta g0 is going to be equal to
negative number of mol electrons
multiplied by Faraday's constant
multiplied by the standard cell
potential now we know that for
spontaneous processes Delta G has to be
negative and since Delta G from this
expression is proportional to the
negative of cell potential so we can
tell that the galvanic cell will always
run in the direction that gives positive
cell potential I hope these videos help
of you so please like share and
subscribe and I'll see you next
about electrochemistry today we will
talk about the relationship between the
cell potential electrical work and free
energy check my previous video on how to
calculate the standard cell reduction
potential I will post a link in the
description below today we will explore
the relationship between thermodynamics
and electrochemistry the work that can
be accomplished when electrons are
transferred through a wire depends on
the thermodynamic driving force this
driving force is defined in terms of
potential difference between two points
on the circuit and therefore the
electro-motive force is going to be
equal to the potential energy which is
equal to a Joule of work for a Coulomb
of charge
now here we'll consider the cell as the
system and since the work is done by the
cell it will be indicated by a negative
sign and therefore the potential energy
is going to be equal to minus W over Q
if we rearrange this expression we will
get that the work is equal to minus Q
multiplied by e max from this equation
it could be seen that the maximum work
that could be obtained at the maximum
cell potential and therefore W max is
equal to minus Q E max it's not worthy
to mention that we can never realize the
maximum work from a cell because of the
wasted energy through frictional heating
when a current flows however we can
measure the maximum cell potential using
an efficient digital voltmeter the
charge can be calculated by knowing the
amount of electrons or number of mole of
electrons passing through the wire and
using Faraday's constant and therefore Q
is equal to number of more electrons
multiplied by for a day's constant for
these law states that the charge of one
more electron is equal to ninety six
thousand four hundred eighty five
coulombs and therefore we have what we
call F which is the Faraday's constant
it's equal to 96 thousand four
hundred eighty-five coulombs per mole
electron and now we can relate the
potential of a galvanic cell to the free
energy we know that full process at
constant temperature and pressure the
change on free energy is equal to the
maximum of useful work and therefore
Delta G is equal to the work maximum and
we know that the work maximum is equal
to minus Q times the cell potential and
we know that Q is equal to number of
mole electrons multiplied by Faraday's
law so if we put all this together we
will have to the change of free energy
it's equal to minus number of mol
electrons multiplied by for a dis
constant multiplied by the maximum at
cell potential for standard conditions
Delta g0 is going to be equal to
negative number of mol electrons
multiplied by Faraday's constant
multiplied by the standard cell
potential now we know that for
spontaneous processes Delta G has to be
negative and since Delta G from this
expression is proportional to the
negative of cell potential so we can
tell that the galvanic cell will always
run in the direction that gives positive
cell potential I hope these videos help
of you so please like share and
subscribe and I'll see you next
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Nov 05, 2024 Last updated |
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