AIM: To determine the Fermi energy of the copper.
APPARATUS: DC Regulated power supply, Milliammeter, Voltmeter, Copper wire and Screw gauge.
PRINCIPLE: The energy of the highest occupied level by an electron at absolute zero temperature is called the Fermi energy. Fermi energy is given by,
EF = ½ mvF2
Where ‘m’ is the mass of the electron and ‘vF’ the Fermi velocity.
But vF = lF/t where lF is mean free path and t the relaxation time.
Since conductivity s = 1/r = L/RA = ne2t/m,
t = mL/ne2RA = mL/ne2Rpr2 [A=pr2 ]
\vF = ne2Rpr2 lF/ mL
Now EF = ½ mvF2 = ½ m (ne2Rpr2 lF/ mL)2
For Copper, n = 8.5 x 1028 /m3
lF = 53 x 10-9 m
e = 1.6 x 10-19 C
m = 9.1 x 10-31 Kg
\ EF = 7.16 x 10-2 x (r4/L2) x R2
But R = slope of the Voltage-Current graph.
\ EF = 7.16 x 10-2 x (r4/L2) x [Slope]2
APPARATUS: DC Regulated power supply, Milliammeter, Voltmeter, Copper wire and Screw gauge.
PRINCIPLE: The energy of the highest occupied level by an electron at absolute zero temperature is called the Fermi energy. Fermi energy is given by,
EF = ½ mvF2
Where ‘m’ is the mass of the electron and ‘vF’ the Fermi velocity.
But vF = lF/t where lF is mean free path and t the relaxation time.
Since conductivity s = 1/r = L/RA = ne2t/m,
t = mL/ne2RA = mL/ne2Rpr2 [A=pr2 ]
\vF = ne2Rpr2 lF/ mL
Now EF = ½ mvF2 = ½ m (ne2Rpr2 lF/ mL)2
For Copper, n = 8.5 x 1028 /m3
lF = 53 x 10-9 m
e = 1.6 x 10-19 C
m = 9.1 x 10-31 Kg
\ EF = 7.16 x 10-2 x (r4/L2) x R2
But R = slope of the Voltage-Current graph.
\ EF = 7.16 x 10-2 x (r4/L2) x [Slope]2
PROCEDURE: The circuit arrangement is made as shown in figure. The voltage is varied gradually and the corresponding current values are noted down. A graph can be plotted with the voltage along Y-axis and the current along the X-axis. The slope of the graph gives the resistance of the given copper material. The radius of the copper wire is measured using a screw gauge and length by using a meter scale.
OBSERVATIONS:
Radius of the wire (r) =
Length of the wire (L) =
Voltage (V) Current (I)
Radius of the wire (r) =
Length of the wire (L) =
Voltage (V) Current (I)
CALCULATIONS:
Slope of the graph = AB/BC =
EF = 7.16 x 10-2 x (r4/L2) x [Slope]2 =
RESULT: Fermi energy of the given material =
Slope of the graph = AB/BC =
EF = 7.16 x 10-2 x (r4/L2) x [Slope]2 =
RESULT: Fermi energy of the given material =
7 comments:
Fermi energy is temperature dependent then how is it possible to get fermi energy without temperature variation
Yes how? I've got the same question
It is not current.
It should be temperature in kelvin scale instead
Ya that is temperature only
What is the result of that experiment?
give me sir sample readings of voltage and current
What are the precautions
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