Thermal and electrical conductivity of metal
SouravGhosh148
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Nov 03, 2018
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About This Presentation
steady-state method to calculate thermal and electrical conductivity
Slide Content
THERMAL AND ELECTRICAL
CONDUCTIVITY OF METAL
SOURAV GHOSH
15208
PHY 405
CONDENSED MATTER PHYSICS LAB
CONDUCTIVITY OF METAL
SOURAV GHOSH
15208
PHY 405
CONDENSED MATTER PHYSICS LAB
AIM OF THE EXPERIMENT
EXPERIMENTAL SETUP
•Determine the thermal conductivity of the metal rod(Copper/Aluminium)
•Determine the electrical conductivity of Copper and Aluminium rod.
•To test the Wiedemann-Franz law and find out the Lorentz number
Source-indosawmanual
EXPERIMENTAL SETUP
•Determine the thermal conductivity of the metal rod(Copper/Aluminium)
•Determine the electrical conductivity of Copper and Aluminium rod.
•To test the Wiedemann-Franz law and find out the Lorentz number
Source-indosawmanual
PROCEDURE
❖Thermal conductivity measurement-
1.Measurement of heat capacity of lower calorimeter
??????=??????
�.??????
�.
??????
??????−??????
??????
??????
??????−??????
??????
Where, ??????
�=Specific heat capacity of water, ??????
�=Mass of water, ??????
??????=Temperature of hot water,
??????
??????=Temperature of mixing, ??????
�=Room temperature
2. Determination of influence of the surroundings-
The addition of heat from the surroundings is calculated from the temperature increase in the lower
calorimeter (for that we have to fill the lower calorimeter with ice and check the temperature of the lower
calorimeter in 1 min interval till the temperature rises to 12 degree Centigrade.
??????=??????�⋅??????
�+??????⋅??????−??????
0
??????
0=Temperature at time t=0
Slope of the graph Q vs t gives us (dQ/dt)surr
3. Determination of the heat flow through metal rod and calculation of thermal conductivity-
ⅆ??????
????????????�
ⅆ??????
=−????????????
Δ??????
Δ�
For that we have to maintain almost constant temperature gradient between the upper calorimeter and
the lower calorimeter at a constant temperature and note the differential temperature and the temperature
of the lower calorimeter .
Now slope of Q-t graph will give us (dQ/dt)total and (dQ/dt)rod=(dQ/dt)total-(dQ/dt)surr
❖Thermal conductivity measurement-
1.Measurement of heat capacity of lower calorimeter
??????=??????
�.??????
�.
??????
??????−??????
??????
??????
??????−??????
??????
Where, ??????
�=Specific heat capacity of water, ??????
�=Mass of water, ??????
??????=Temperature of hot water,
??????
??????=Temperature of mixing, ??????
�=Room temperature
2. Determination of influence of the surroundings-
The addition of heat from the surroundings is calculated from the temperature increase in the lower
calorimeter (for that we have to fill the lower calorimeter with ice and check the temperature of the lower
calorimeter in 1 min interval till the temperature rises to 12 degree Centigrade.
??????=??????�⋅??????
�+??????⋅??????−??????
0
??????
0=Temperature at time t=0
Slope of the graph Q vs t gives us (dQ/dt)surr
3. Determination of the heat flow through metal rod and calculation of thermal conductivity-
ⅆ??????
????????????�
ⅆ??????
=−????????????
Δ??????
Δ�
For that we have to maintain almost constant temperature gradient between the upper calorimeter and
the lower calorimeter at a constant temperature and note the differential temperature and the temperature
of the lower calorimeter .
Now slope of Q-t graph will give us (dQ/dt)total and (dQ/dt)rod=(dQ/dt)total-(dQ/dt)surr
PROCEDURE…CONTINUED
❖Electrical Conductivity Measurement
–Connected the experiment setup according to the circuit
–Slowly increased the current value in power supply and noted the values of current and voltage
–From the V-I graph slope we will get R
–As we know, ??????=
??????
??????�
where , ??????= electrical conductivity, L=length of the rod, A=cross section
area of hot end
❖Electrical Conductivity Measurement
–Connected the experiment setup according to the circuit
–Slowly increased the current value in power supply and noted the values of current and voltage
–From the V-I graph slope we will get R
–As we know, ??????=
??????
??????�
where , ??????= electrical conductivity, L=length of the rod, A=cross section
area of hot end
THEORY
•Thermal conductivity of a material is a measure of its ability to conduct heat.
•The quantity of heat transported with time dt is a function of the cross-sectional area A and
the temperature gradient ΔT/Δxperpendicular to the surface.
��
�??????
=−????????????
Δ??????
Δ�
….. |a| ??????=thermal conductivity of the material
•The temperature distribution in a body is generally a function of location and time and is in
accordance with the Boltzmann transport equation
�??????
�??????
=
??????
��
⋅
�
2
??????
��
2
….|b|
•After some time, a steady state is reached when the two ends are maintained at constant
temperature.
�??????
�??????
=0
•In order to calculate the heat energy transported by the metal rod according to(a), the
ambient contribution from the surroundings must be subtracted
���????????????
�??????
=
���??????�
�??????
−
���
�??????
•Thermal conductivity of a material is a measure of its ability to conduct heat.
•The quantity of heat transported with time dt is a function of the cross-sectional area A and
the temperature gradient ΔT/Δxperpendicular to the surface.
��
�??????
=−????????????
Δ??????
Δ�
….. |a| ??????=thermal conductivity of the material
•The temperature distribution in a body is generally a function of location and time and is in
accordance with the Boltzmann transport equation
�??????
�??????
=
??????
��
⋅
�
2
??????
��
2
….|b|
•After some time, a steady state is reached when the two ends are maintained at constant
temperature.
�??????
�??????
=0
•In order to calculate the heat energy transported by the metal rod according to(a), the
ambient contribution from the surroundings must be subtracted
���????????????
�??????
=
���??????�
�??????
−
���
�??????
WIEDEMANN-FRANZ LAW..
RELATION BETWEEN ELECTRICAL CONDUCTIVITY AND THERMAL CONDUCTIVIT Y
•At room temperature the conduction electrons in metal have much greater mean free path
compared to phonons and therefore heat conduction in metals is primarily due to the
electrons. The correlation between the thermal conductivity λand electrical conductivity σis
given by the Wiedemann Franz law-
??????
??????
=??????⋅??????
where ??????= thermal conductivity , ??????= electrical conductivity , L=Lorentz number
theoretical value of L,
??????=
�
2
3
⋅
??????
2
ⅇ
2
=2⋅4×10
−8
�??????
??????
2
RELATION BETWEEN ELECTRICAL CONDUCTIVITY AND THERMAL CONDUCTIVIT Y
•At room temperature the conduction electrons in metal have much greater mean free path
compared to phonons and therefore heat conduction in metals is primarily due to the
electrons. The correlation between the thermal conductivity λand electrical conductivity σis
given by the Wiedemann Franz law-
??????
??????
=??????⋅??????
where ??????= thermal conductivity , ??????= electrical conductivity , L=Lorentz number
theoretical value of L,
??????=
�
2
3
⋅
??????
2
ⅇ
2
=2⋅4×10
−8
�??????
??????
2
RESULTS…
COPPER
COPPER
RESULTS…
ALUMINIUM
ALUMINIUM
RESULTS
❖Copper
➢Heat Capacity of calorimeter = 58.17 Cal/K
➢Thermal conductivity, λ= 200.34 W/m-K
■Literature value = 385 W/m-K
➢Electrical conductivity, σ= 5.185*107 S/m
■Literature value = 5.96*107 S/m
➢Lorenz number, L = 1.305*10-8 W-Ω/K2
■Literature value = 2.44*10-8 W-Ω/K2
❖Copper
➢Heat Capacity of calorimeter = 58.17 Cal/K
➢Thermal conductivity, λ= 200.34 W/m-K
■Literature value = 385 W/m-K
➢Electrical conductivity, σ= 5.185*107 S/m
■Literature value = 5.96*107 S/m
➢Lorenz number, L = 1.305*10-8 W-Ω/K2
■Literature value = 2.44*10-8 W-Ω/K2
RESULTS
❖Aluminium
➢Thermal Conductivity, λ= 89.46 W/K-m
■Literature value = 205 W/K-m
➢Electrical Conductivity, σ= 3.352*107 S/m
■Literature value = 3.77*107 S/m
➢Lorenz Number, L = 0.9*10-8 W-Ω/K2
■Literature value = 2.44*10-8 W-Ω/K2
❖Aluminium
➢Thermal Conductivity, λ= 89.46 W/K-m
■Literature value = 205 W/K-m
➢Electrical Conductivity, σ= 3.352*107 S/m
■Literature value = 3.77*107 S/m
➢Lorenz Number, L = 0.9*10-8 W-Ω/K2
■Literature value = 2.44*10-8 W-Ω/K2
|| T H A N K Y O U ||
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