planck’s constant in the light of an incandescent lamp
TRANSCRIPT
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Planck’s constant in the light of an
incandescent lamp
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Introduction
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The idea of light quanta
• Planck (1900): emission of radiant energy by matter does not take place continuously, but in finite “quanta of energy” h (h= Planck’s constant 6.63x10-34 J.s, =frequency)
• Einstein (1905): light quanta (photons) as inherent in the nature of radiation itself
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Distribution of intensity of heat radiation as a function of the wavelength
:Emissivity
(=1 for perfect
black-body radiation)
C1, C2 :
Constant parameters
1
25
1
T
c
e
cu
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Where c2=hc/kh: Planck’s constant
c: velocity of light
k: Boltzmann’s constant
1
25
1
T
c
e
cu
Planck’s radiation law Radiation energy per time unit for the
wavelength
Main objective of this experiment
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Report on the experiment
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Emission of a 12 V tungsten lamp
u
wavelength,
12
5
1
T
c
e
cu
12
5
1
T
c
e
cu
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The light spectrum emitted by the filament is continuous.
u
wavelength,
12
5
1
T
c
e
cu
12
5
1
T
c
e
cu
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u
wavelength,
12
5
1
T
c
e
cu
12
5
1
T
c
e
cu
Liquid filter
0
A narrow band of the visible spectrum is selected with a combination of Orange II and Copper Sulphate solution
(it absorbs infrared strongly).
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12
5
1
T
c
e
cu
12
5
1
T
c
e
cu
We will assume that the selected band is nearly monochromatic.
u
wavelength,
Liquid filter
0
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12
5
1
T
c
e
cu
12
5
1
T
c
e
cu
The wavelength of the selected band is in the spectral response range of a Light Dependent Resistor (LDR)
Liquid filter
0
u
wavelength,
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From the formula:
For small
Resistance R of LDRis related to illumination as:
lllumination E on the LDR is proportional to the transmitted energy
(3) 0uE (3) 0uE
(4) EbR (4) EbR
(1)
12
5
1
T
c
e
cu
(1)
12
5
1
T
c
e
cu
b: constant : parameter
Taking logarithms
(5) 0
2
3T
c
ecR
(5) 0
2
3T
c
ecR
(2) 0
20
50
1
T
c
e
cu
(2)
0
20
50
1
T
c
e
cu
Combining (2), (3) and (4):
(6) 1
lnln0
23 T
ccR
(6) 1
lnln0
23 T
ccR
Plotting
lnRldr
1/ T
2c2c
h
Block diagram
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Experimental setup
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GENERAL DIAGRAM
Voltmeter
Lamp
Ammeter
Potentiometer
Battery
Solution filter
LDR
Ohmeter
V
A
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COMPONENTS
Platform
Potentiometer
Battery
Lamp
AV
LDR
Cover
Ruler
Solution filter
Holder
Grey filter
Voltmeter AmmeterOhmeter
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INSTALLINGINSTALLING
THETHE
EQUIPMENTEQUIPMENT
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11 Turn the potentiometer knob anticlockwise up to
the limit
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22 Turn slowly the
tube holder aligning the lateral holes between the
lamp and the LDR.
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Move the LDR towards its lateral
hole, positioning its surface as the figure
shows.
33
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Insert the solution filter
tube in its holder.
44
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Put the cover onto the platform to protect
from the outside light.
In order to ensure the correct initial
conditions, LDR should keep in total
darkness for at least 10 minutes before the
measurements.
55
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Procedure
(6) 1
lnln 23 T
ccR
(6) 1
lnln 23 T
ccR
Some previous
measurements are needed before using
Equation (6)
TT
00
RR
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RB0 can be extrapolated to I = 0 from measurements
of V and I,
RB0 can be extrapolated to I = 0 from measurements
of V and I,
83,0BaRT 83,0BaRT
V
A
Relation between the resistance of the filament (RB)
and its temperature (T)
Relation between the resistance of the filament (RB)
and its temperature (T)
a can be derived from the filament resistance (RB0) at room temperature (T0)
a can be derived from the filament resistance (RB0) at room temperature (T0)
R
Ta
B83.0
0
0
R
Ta
B83.0
0
0
Using the multimeter
as a thermometer.Using the multimeter
as a thermometer.
I
R
R0
T Temperature of the emmitting filament
RB
RB0
Experimental data fit
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transmission of the filter
Solution of:
- Orange II.
- CuSO4 (it absorbs the infrared light).
Solution of:
- Orange II.
- CuSO4 (it absorbs the infrared light).
0
5
10
15
20
25
30
35
450 500 550 600 650 700 750
/nm
% transmitance 0 = 590 nm0 = 590 nm
/nm
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Parameter of the LDR
En Rn
0.512En Rn’
Grey filter
bERn
)512.0(' EbRn
512.0lnln'
n
n
R
R
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RV
A
COLLECTING DATA
VI RRB=V/I T = aRB0.83 RB
-0.83 lnR
RB-0.83
lnR
a
cm
0
2
a
cm
0
2
V1I1 R1RB1 T1 RB1-0.83 lnR1
V2I2 R2RB2 T2 RB2-0.83 lnR2
V3I3 R3RB3 T3 RB3-0.83 lnR3
VnIn RnRBn Tn RBn-0.83 lnRn
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a
cm
0
2
a
cm
0
2
RB-0.83
lnR
From the slopeFrom the slope
We obtainWe obtain
am
c 02
am
c 02
And finally the Planck´s constant:And finally the Planck´s constant:
c
kch 2
c
kch 2
h: Planck´s constant.
k: Boltzmann´s constant.
c: speed of light.
h: Planck´s constant.
k: Boltzmann´s constant.
c: speed of light.
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End of presentation