RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Page 1 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Expt. No. -
Date:
Determination of the band gap of a semiconductor by four probe method and identify the semiconductor material Apparatus:
Sl. No. Name of apparatus 1. Semiconductor wafer 2. Four probe arrangement 3. Thermometer 4. oven
Specification
Range and resolution
Centigrade
0 – 110 110o C
Working formula:
Band gap energy
Eg = 2 x k B T x (log10 ρ) Or,
Eg = 2 x 8.6 x 10 -5 x (log10 ρ)/ T-1
k B = Boltzman constant = 8.62 x 10-5 eV/K Where the resistivity ρ = ρ0 / G7 Here
ρ0 = (V/I) 2πS
V= potential difference between inner probes I = Current flowing through outer probes G7 G7 (W/S) is the correction term (i.e. correction factor is function of W & S) = 5.89 S = distance between two successive probes = 0.2 cm W = Thickness of the crystal = 0. 05 cm T = Temperature of the sample in K Principle of experiment:
The resistivity depends on the temperature of the sample, the band gap on the other hand depends on the resistivity. Hence by changing the temperature of the sample, the resistivity can be altered, a relation between temperature-resistivity data and band gap of the semiconductor. semiconductor. The temperature of course should be given in absolute scale.
Page 2 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Procedure: 1. Insert the thermometer through the hole of the oven 2. Turn on the apparatus. Set the current on 4 mA. 3. Note down the temperature and the voltage obtained. 4. Turn on the oven. Record the temperature and the voltage starting from 30 oC at an interval of 5oC up to at least 100oC. 5. Turn off the oven. Record the voltages at the same temperature while temperature is decreasing. Calculate the average voltage at each temperature. 6. Draw a graph from the given table 7. Calculate G(W/S) from the graph. Calculate . Convert the temperature into Kelvin. 8. Plot a graph of log vs 1/T. Determine the slop from the linear part 9. Eg/2K = slope of the graph Thickness of the crystal (w) = 0.07 cm Distance between the prob (s) = 0.2 cm The value of K = 1.38 x 10-23 J/K Standard value of Eg in Joule = 1.12 X 10 -20 J = 0.3 eV 1eV = 1.6 x 10 -19 J
Observation: A) To determine the resistivity (ρ) at different temperature (T) during cool ing at constant
current I = 4 mA. Table - I
Sl. No.
Temp. ( 0C)
Voltage Voltage when when temperature temperature decreasing decreasing (mV)
(mV)
Up to room temperature Result:
Eg = 2 x 8.6 x 10 -5 x (log10 ρ) / T-1 Page 3 of 29
Temp (K)
ρ in Ω
cm
T-1 x 103 (K -1)
Log10 ρ
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Eg = 2 x 8.6 x 10 -5 x (slope of the graph log 10 ρ vs. T-1) Discussion:
1) 2) 3) 4) 5)
The probes should be just touching the wafer The temperature should be taken at intervals of ~ 10 0C The current should be kept constant at ~ 4 mA The maximum temperature should be about 120 K When the current starts to vary, the data should no further be taken.
Viva voce questions: 1. What is energy band gap?
The gap between the bottom of conduction band and the top of valence band is called Energy gap. To move the electrons from the valence band to conduction band the supplied external voltage must be equal to energy band gap. 2. What is valence band?
Ans: The range of energy which is possessed by valence electrons is known as valence band. Here the electrons which are situated at outer most orbits are called valence electrons. The valence band consists of valence electrons which are having highest energy. 3. What do you mean by conduction band?
The range of energies possessed by conducting electrons is known as conduction band. The conduction electrons are responsible for the conduction of current in a conducting material. So, these electrons are called as conduction electrons. 4. How energy bands are generated in a semiconductor?
A semiconductor remains in crystalline form. In such a crystal, the constituent atoms are orderly arranged., so the unfilled energy levels of the crystal atoms merge together to form an energy band called the conduction band and the filled and partially filled energy levels merge together to form valence band. In a semiconductor there remains gap between conduction and valence band called band gap. 5. Classify the solid materials on the basis of energy gap.
Ans: Based on the energy gap the solid materials are classified into 3 types they are: conductors, insulators and semi conductors. 6. Define conductors, insulators and Semi conductors.
Page 4 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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Conductors: Those substances whose atoms have their outermost orbits incomplete are
known as conductors (e.g. Cu, Ag, Au etc.). In conductors, valence and conduction bands are found overlapped into each other i.e. the energy gap is zero. Insulators: Those substances which have large energy gap between their valence and
conduction band, are called insulators (e.g. diamond, wood etc.). Semi conductors: Those substances which have conductivity and resistivity properties in
between conductors and insulators are called semi conductors (e.g. Si, Ge). Energy gap of these semiconductors lies between 0.5 to 1.1eV (Foe Ge it is 0.5 – 0.7eV). 7. How many types of semi conductors are there?
Two types of semi conductors are there (i) Intrinsic or pure semi conductors and (ii) Extrinsic or impure semi conductors. 8. Define intrinsic and extrinsic semi conductor? Intrinsic semi conductor: A pure semiconductor is known as intrinsic semi conductor. In
these semi conductors, if the temperature increases then the conductivity is also increases. At higher temperatures due to collisions some electrons absorb energy and raises to conduction band then in their places in valence band holes are created. In intrinsic semiconductor number of holes is equal to number of electrons. Extrinsic semi conductor: A pure semiconductor after doping is called extrinsic or impure
semi conductor. Trivalent and penta-valent impurities are added to form P-type and N-type semiconductors respectively. 9. What do you mean by Fermi energy level?
The level upto which all the energy states are filled by electrons is known as Fermi level. The average energy of charge carriers is calculated by Fermi energy level. In pure semi conductors Fermi energy level is at the centre of the valence and conduction bands. In extrinsic/impure P-type (N-type) semiconductor Fermi energy level is near to the valence (conduction) band. 10. Define Doping and Dopant?
The process of adding impurities to a pure semi conductor is called doping The material added as impurity is called as Dopant. 11. What are P-type and N-type semi conductors?
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RCC Institute of Information Technology Paper Code: PH 391/491
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If we add trivalent impurities such as Aluminum to a pure semi conductor then the material is called P-type semi conductor. If a pentavalent impurity such as Arsenic is added to a pure semi conductor then the material is called N-type semi conductor 12. Why P-type (N-type) semi conductor is called Acceptor (Donor)?
In P-type material 3 electrons of trivalent atom makes covalent bonds with Semiconductors such as Si or Ge and there is a need of one more electron to make the system stable because Si or Ge has 4 electrons in their outermost orbits. For this reason P-type material is also known as Acceptor. On the other hand, in case of N-type of material 4 electrons of pentavalent atom makes covalent bonds with Semiconductors such as Si or Ge which have 4 electrons in their outermost orbits and hence there is one free or excess electron remains present in the structure. For this reason N-type material is also known as Donor. 13. What is P-N junction diode?
If P-type and N-type semi conductors are combined to each other then the resultant structure is called P-N junction diode. This means if trivalent impurity is doped to one end of the pure semi conductor and pentavalent impurity to other end, a P-N junction diode can be formed. 14. What is 4 probe method ?
In this method a wire or a small structure is contacted at 4 locations.
A
V Probe
15. What for 4 probe method is used ?
Semiconductor
It is used to determine the specific S
resistivity (Ωm) of metal line during
S
S
electrical characterization of metallic deposition of thin metal line. 16. What is the principle used in 4 probe method ?
Current is forced through outer pins 1 & 4 & a drop voltage across pins 2 & 3 is measured using a very high through pin 2 & 3 is nearly 0. In these case the individual n additional contact resistance does not play a role as it cancels out of the equations. 17. What is an ohmic resistor ?
If the behavior of the structure of I/V curve is a straight line. Then the structure behaves as ohmic resistor. 18. What is the advantage of 4 probe method over other methods of measuring resistivity?
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RCC Institute of Information Technology Paper Code: PH 391/491
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In most of other methods, the current carrying contacts injects minority carriers which ultimately modify the resistance of the material. 19. What is meant by electrical resistivity ( )?
It is the property of the material by the virtue of which it opposes the flow of current. It is also defined as the reciprocal of electrical conductivity (Ωm) -1 . Its unit is Ωm i.e., = l/ = RA/L. 20. What are the values of band gap in the case of germanium and silicon?
For Ge the band gap value is 0.785 eV, for Si the band gap value is 1.21 eV at 0K.
Page 7 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Expt. No. -
Date:
Determination of Hall coefficient of semiconductor Apparatus:
Sl. No. 1. 2. 3. 4. 5.
Name of apparatus Hall effect setup Standard semi-conductor probe Electromagnet Constant current power supply Gauss meter with hall probe
Specification
Range and resolution
DC, Digital Digital, InAs
I N
I
S
VH
t
Working formula: Hall co-efficient R H
Where,
1 nq
V H t I H
n = no. density of charge q = charge of carrier VH = hall voltage t = thickness of the material I = current through semiconductor sample H = magnetic field
Principle of experiment:
Effect of Lorentz force on moving charge particles through transverse electric and magnetic field. Observation: B) Calibration of magnetic field (H) with respect to current (I em) through electromagnet
Page 8 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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Table - I No. of observation
Iem (amp)
H (gauss)
0.5 1 1.5 Upto 4 amp. C) Measurement of hall voltage (V H) with respect to varying current (I) through sample for constant magnetic field (H ≈ 1000 G) Table – II
I (mA)
VH (mV)
D) Table – III (Repeat Table – II for H ≈ 3000 G) E) Measurement of hall voltage (V H) with respect to varying magnetic field (H) for constant current through sample(I ≈ 1 mA) Table - IV
Iem (amp)
H (gauss)
VH (mV)
F) Table – V (Repeat Table – IV for I ≈ 3mA) V t -1 -1 Result: Hence Hall co-efficient R H H volt. cm. amp . gauss I H Discussion:
1) Sample should be placed at the middle of pole pieces and perpendicular to the magnetic field. 2) Magnetic polar metal beams should be of equal length from both the coils. 3) Space between the pole pieces should be around 3 cm. 4) There should not be any other disturbing magnetic field near the apparatus. Page 9 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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5) Care should taken to limit the current through the probe to a value less than that mentioned by the manufacturer. Viva voce questions:
1. Define Hall Effect?
When a current carrying specimen is placed in a transverse magnetic field then a voltage is developed which is perpendicular to both, direction of current and magnetic field. This phenomenon is known Hall Effect. 2. What causes Hall Effect?
Whenever a charge moves in a mutually perpendicular electric and magnetic field it experiences Lorentz force due to which it deflects from its path and Hall voltage is developed. 3. What is Lorentz force? If charge ‘q’ moves in a magnetic and electric field ‘B’ &’E’ respectively with ve locity v then force on it is given by F= qE+ Bqv.sinө 4. What is Hall Coefficient?
It is the electric field developed per unit current density per unit magnetic field 5. What are the uses of Hall Effect?
To determine the sign of charge carrier and charge carrier concentration 6. Define Charge carrier concentration.
No. of charge carriers per unit volume. 7. Why Hall voltage differ for different type of charge carrier?
Because direction of Lorentz force is different for different type of charge carrier. 8. What is unit Hall coefficient?
Ohm-meter/Tesla. 9. What is the unit of charge carrier concentration
Per Cubic-centimeter. Page 10 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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10. Which type of magnet is used in the experiment, temporary or permanent?
Temporary. 11. Mention some uses of the Hall effect
(i) Determination of the semiconductor type. Since R H is positive for a p-type semiconductor (ii) Determination of the carrier concentration .Since R H
1 ne
or
1 pe
(iii) Measurement of unknown magnetic field. The hall voltage VH is proportional to the magnetic field H for a given current I through the specimen. Thus knowing the sample dimensions and R H, the magnetic field can be determined by measuring I and V H.
Page 11 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
EXPT. NO. -
DATE:
Determination of Planck’s constant ‘h’ by measuring radiation in a fixed spectral range Apparatus:
Name of apparatus
Specification
Range and Resolution
Planck’s constant kit having
a) b) c) d) e) f)
Photodiode Filament bulb Potentiometer Ammeter Voltmeter Microammeter
Single point 12 V, DC 0 - …… , …….. A 0 -……. , …….. V 0 - ……, …….. µA
Digital
Procedure & Results: 1. Turn on the system. Turn on the voltage control knob an very carefully observe when exactly the knob start glowing. Note the voltage and current and hence resistance of the knob. This is Rg. TableI: Determination of Rg
No. of Obs.
Voltage (V)
Current (A)
Resistance (Ohm)
(R g
) Avg. Resistance (R g ) (Ohm)
1. 2. 3. 2. Increase the voltage in small steps (0.5 V) and record the current and hence calculate the resistance. These are the values of R. Note also the photocurrent, . Table II: To find the resistance and hence temperature
Voltage(V )
Current (A) Resistance R(ohm)
R/R g T from 1/T (10- ) (K - ) equation 1
Page 12 of 29
Photocurrent
In
RCC Institute of Information Technology Paper Code: PH 391/491
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3. From the below table of R/Rg and T draw a graph (T vs R/R g ). Use this graph to determine the temperature; T of the filament from the experimentally observed value of R/Rg obtained in step 1 and 2. Calculate 1/T.
T 150.141 634.007( R R g )
-------- (1)
4. Draw a graph of ln vs. 1/T. 5. Determine h from the slope of this curve and from the equation
Where, -10 -23 8 = 6000 X 10 m, k = 1.38 X 10 J/K, c = 3 X 10 m/s Standard value of Plank constant is 6.6 X 10 -34 Js
Discussions:
1. The setup should be initialized as follows: the light source should be turned away from the photocell and the ammeter dial adjusted so that it reads 0 for zero input voltage in presence of laboratory light. 2. The source light is then turned towards the photocell and the value of I for V = 0 recorded. 3. For small increments of V, I is recorded. After I saturates (or even before that, as all we are interested in is the stopping potential), we stop taking readings for increasing V. V is returned to the value V=0, the polarity of the connections to the photocell reversed by switching the wires, and V is again changed in small steps until I=0. The value of V obtained now is the stopping potential V S.
Viva voce questions:
1. Define Photoelectric effect?
When light falls on metal surface, an electron is emitted from a metal if the energy of the photon is greater than the work function of the metal. Page 13 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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2. What is Reverse Photoelectric effect?
If an electron of sufficient voltage is passed across a material then a photon is emitted whose energy is equivalent to the work function of that material. The voltage at which this effect observed is the ‘turn on voltage’. In case of LED reverse photoelectric effect works. 3. Can we observe reverse photoelectric with Metal surface?
This effect is not normally observed in metals and other typical substances because the photons emitted are usually outside the range of visible light, usually somewhere in the infrared Range. 4. What is the full form of LED?
Full form of LED is Light Emitting Diode. 5. What is Planck’s constant (h)? What is the standard value of h.
It is a fundamental physical constant. It gives the order of energy exchange in case of quantum mechanical action. It is the ratio of energy of a photon of its frequency. h= 6.6x10 -34 Js. 6. What is LED?
A light-emitting diode (LED) is a semiconductor device that emits visible light when an electric current passes through it. 7. What is photo voltic cell?
It is a p-n junction which can convert light energy into electrical energy. 8. In which factor the stopping potential of a particular colour of light depends?
The stopping potential of a particular colour of light depends on its frequency and the stopping potential is directly proportional to its frequency. 9. In which factor the maximum value of the the photo current depends?
The maximum value of the photo current depends on the intensity of the incident light.The photo current is directly proportional to the intensity of the incident light. 10. Why the green light has large stopping potential than red light? The energy of green wavelength is more than that of red. So the frequency of green is more than red. Since stopping potential is directly proportional to the frequency of the particular colour incident light. Thus due to high value of frequency green has large stopping potential than red. Page 14 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
EXPT. NO. -
DATE:
DETERMINATION OF STEFAN’S CONSTANT USING A VACUUM TUBE DIODE (TYPE EZ-81 EMISSION) APPARATUS: Item No.
Name of Apparatus
1.
Stefan’s constant kit having
Specification
Range & Resolution
a) Vacuum diode made of main Diode model: components as EZ-81 i. cylindrical cathode made of nickel and coated with BaO &SrO mixture outside. ii. electrically insulated tungsten heater filament with a thin coating of plaster of paris, closely fitted with the nickel cathode and placed inside it. DC Digital Digital
b) Power supply c) Voltmeter d) Ammeter WORKING FORMULA:
If we neglect the power loss due to conduction and convection then we can write Stefan’s law
as Or, And R-T relation for tungsten is
Where V f = filament voltage I f = filament current = emissivity of the cathode
surface = 0.24 S = 2 r l = surface area of the cathode r = radius of the cathode = 0.12 x 10 - 2 m = 0.0012 m Page 15 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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-2
l = length of the cathode = 3.12 x 10 m = 0.0312 m T = Temperature of tungsten filament in Kelvin RT = Temperature coefficient of resistance Principle of experiments: Applying Stefan’s law to the heated cylindrical cathode due to tungsten filament, we can determine Stefan’s constant from the knowledge of the surface area and the emissivity of
the cathode which is less than unity in this case as the radiation from cathode by thermionic emission process is not from an ideal black body. Observation: A) Determination of filament temperature from the standard graph data of T vs. R T/R 300: Table - I Sl. No. T in (K) R T/R 300
1 2 3 4 5 Given: R 300 = 0.6 Ω
1 4 6 8 10
300 920 1300 1645 1990
OR B) Characteristics of filament: Table - II Sl. No. 1 2 3 4 5 6 7 8 9
V f (volt) 0.2 0.4 0.6 0.8 1 2 3 4 5
I f (amp)
R T = V f / I f P = V f I f (Ω)
(watt)
R T /0.6
T
Log P
(K)
Result: Hence measured value of Stefan’s constant = ……………………… w m- 2 K - 4
Discussions:
Page 16 of 29
Log T
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
1. In taking readings between V f and I f every reading should be taken after getting steady state or the time difference between each reading should be approximately 3 to 4 minutes. 2. In plotting the graph between log P and log T the experimental point at the lower end of temperature state lies outside the straight line graph, since corrections due to heat power loss are neglected. At high temperature these losses are not negligible and so in fig.-2 the straight line is drawn through such points. 3. It should be necessary to determine the slope of the straight line as accurately as possible to verify the Stefan’s law within experimental errors.
Viva voce questions:
1. What are meant by black body?
Black body is the one which absorbs all radiation which incident on it. On heating black body stats emitting radiations called black body radiation which are independent of nature of body and depends on the temperature of black body. 2. Why black body is called as black body?
Due to the fact that whatever may be the color of incident radiation the body appears black. 3. How does this law differ from Newton’s law of cooling ? Newton’s law of cooling is applicable only when the difference of temperature between the body and the surroundings is very small. This law , in fact, can be deduced from Stefan‟s law
assuming the temperature difference as small. 4. Can the value of Stefan’ s constant be determined from this method ?
Yes, taking the value of as 4, the value of C can be obtained from E = σ (T 4 – T 4 0) or from the value of the intercept of the graph also, the value of C can be obtained from P = log C + nlog T, if the radiating body is not assumed as a black body. Assuming this to be a black body, this value of C so obtained will correspond to the Stefan‟s Law.
5. Is this method superior to the conventional thermal method ? This method id though not very precise and accurate. However it has some points of advantages. The bulb is never truly a black body and at steady state, the power radiated is never equal to V . I exactly. The working theory in this method is to some extent approximate, nevertheless, the method is very simple and the accessories are easy to procure.
Page 17 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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It gives an approximate idea about Stefan‟s Law, Stefan‟s constant and the verification of the
law. 6. State Stefan’ s law.
It states that total radiant energy emitted per second from the unit surface area of a perfectly black body is proportional to the fourth power of its absolute temperature. 7. What is Stefan’ s constant ?
If E denotes the total energy emitted per second from unit surface area of a black body then by Stefan‟s law, we have E = T 4 . 8. Do you know about Kirchoff‟s law of black body radiat ion?
It states that at any temperature, the ratio of emissive power of the absorptive power of a given wavelength is same for all bodies. 9. What is emissive power and absorptive power?
Emissive power: At a particular temperature and for a given wavelength, it is defined as the radiant energy emitted per unit time per unit surface area of the vody within a unit wavelength range. Absorptive power : At a particular temperature and for a given wavelength, it is defined as the ratio of the radiant energy absorbed per second per unit surface area of the body to the total energy falling per unit time on the same area. 10. State Wein’ s law?
The wavelength corresponding to the maximum energy is inversely proportional to the absolute temperature. 11. Explain the distribution of black body radiation spectrum?
The amount of energy radiated by a black body id not uniformly distributed over all the wavelength emitted by the body but it is maximum for a particular wavelength. The value of wavelength is different for different temperature and varies with temperature. 12. Define solar constant?
Solar constant defined as the amount of energy received / sec/unit area of a perfect black surface at a mean distance of the earth from the sun in the absence of earth‟s atmosphere, the
surface being perpendicular to the direction of sun rays. (1.34 KW/m).
Page 18 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Expt. No. -
Date:
To determine the Rydberg’s constant by studying Hydrogen spectrum (with the help of diffraction grating)
Apparatus: Item No. Name of apparatus 1 Spectrometer 2 Grating
Specification
Range & Resolution
Glass/plastic ………. Lines/cm
3 4
Hydrogen discharge tube Induction coil
Working formula: 1 1 R H 2 2 ………..(1) n1 n2 = wave length of the spectral line. R H = Rydberg’s constant (to be determined) n1 , n 2 = quantum numbers 1
Where,
Knowing , n1 & n2 , R H can be determined from eqn. (1). {Notes: (Don’t write it in lab. Note Book)
Series Lyman
n1 1
Balmer
2
n2 2
3
4
5
3 H (Red
5 H (Blue
6 H (Violet
=4342 Å)
=4102 Å)
6
7
7 8
8 9
Paschen
3
4
4 H (Greenish blue =4861 Å) 5
Brackett Pfund
4 5
5 6
6 7
=6583 Å)
Property Infrared (invisible) Visible
Ultraviolet (invisible) ,, And so on
Balmer series : When an electron jumps from outer orbit to the second orbit , we obtain the Balmer series i.e., this a series for which n 1 = 2 and n2 = 3,4,5,…etc. this series lies in the visible region of the spectrum. } To find wavelength :
where,
sin nN
= angle of diffraction
Page 19 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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n = order of primary maximum. N = number of lines per cm ruled on the grating Observation:
Determination of the vernier constant of the spectrometer: 1 smallest division in main scale =
1 3
degree
Now 60 vernier division = 59 main scale division 1
,,
,,
Vernier Constant (v.c)
=
59
,,
60
,,
,,
= 1 main scale division – 1 vernier scale division 59 = 1 main scale division 60 = =
1
1
degree
60 3 1
60 3
60 minute = 20 seconds
Determination of angle of diffraction: n1=2 and n2 =……….. (…………….colour) (See the notes portion above) Table: 1
Sl. No.
Reading of Telescope for the spectrum on
m u r t c e p s f o r e d r O
1 2
e l a c S r e i n r e V f o s d n i K
Left side(a) ) ) g g e e d d n n i i ( ( l R a S R t o M V T
Direct (b) ) ) g g e e d d n n i i ( ( l R a S R t o M V T
Angle of diffraction (in deg)
Right side (c) ) ) g g e e d d n n i i ( ( l R a S R t o M V T
V1 V2 V1 V2
Table 2:
(Repeat the above table for another visible colour light)
Page 20 of 29
) a ~ b = L
( t f e L
) b ~ c = R
2 / )
2 / ) 2
R
+ L ( =
v
( t h n g a e i R M
v
+ 1 v
( =
n a e M
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Result: Hance the Rydbarg constant R H
1
1
1
1 2 2 n 1 n 2
1
= …………… cm – .
Discussion:
1. Before performing the experiment, the spectrometer should be adjusted. 2. Grating should not be touched by fingers. 3. Grating should be set normal to the incident light. 4. Both verniers should be read. 5. While taking observations, telescope and prism table should be kept fixed. Verification of R H: (Don’t write it in lab. Note Book)
R H=22me4/ch3 Where,
= 9.106 x 10 -28 gm = 4.8025x 10-10 e.s.u h = Planck’s constant = 6.625 x 10-27 ergs-sec c = speed of light in vacuum = 2.998 x 1010cm/sec.
m = mass of an electron e = electronic charge
Viva voce questions:
1. What is diffraction?
The process by which a beam of light or other system of waves is spread out as a result of passing through a narrow aperture or across an edge, typically accompanied by interference between the wave forms produced. 2. What is diffraction grating ?
It is an optically flat glass plate on which large number of equidistant parallel lines are ruled by a fine diamond pen. 3. Mention the two types of diffraction?
i) Fresnel diffraction ii)Fraunhofer diffraction 4. What is the type of diffraction in the diffraction grating experiment?
Page 21 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Fraunhofer diffraction is involved because the source and the screen are effectively at infinite distance. 5. What is grating element?
It is the distance between the centers of any two successive ruled lines or transparent stripes. 6. What is the difference between prism and grating spectrum?
In grating spectrum violet color is least deviated and red color is most deviated but in prism the reverse is true. 7. When will the even order spectra disappear?
They will disappear if the size of opaque lines and transparent stripes is made equal. 8. Why does red color deviate the most in case of grating?
This is so because in case of grating sin θ=n λ/(e+d) i.e angle of diffraction is proportional to the wavelength and the wavelength of red is maximum. 9. What gives a more intense spectrum – prism or grating?
A prism gives more intense spectrum because in prism entire light is concentrated into one spectrum while in the case of grating light is distributed in the grating spectra of different orders. 10. Why is light incident on the side of grating which has no rulings?
To avoid refraction of diffracted light. 11. Define dispersion of light.
The process of splitting of white light into it’s constituent colors is called dispersion of light. 12. Describe essential parts of spectrometer .
Collimator, prism table, telescope. 13. Why do we need two vernier scales?
To remove the error in reading due to not coinciding the axis of prism table and telescope. 14. Name two types of spectra.
Emission spectra, Absorption spectra Page 22 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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15. What is Rydberg constant ?
It is a physical constant relating to atomic spectra in the science of spectroscopy. This constant R is named after Swedish physicisi Johannes Rydberg. The value of Rydberg constant is given by 1.097 X 10 7 m-1 16. What does Rydberg constant represents?
This constant represents the limiting value of the highest wave number of any photon that can be emitted from the hydrogen atom or alternatively the wave number of the photon capable of ionizing the hydrogen atom from its ground state. 17. What is wave number? It is the inverse of the wavelength of a photon. Sometimes inverse of wavelength is multiplied by 2. 18. What is spectrometer? It is an instrument used for analyzing the spectrum of a source of light.
Page 23 of 29
RCC Institute of Information Technology Paper Code: PH 391/491
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Expt. No. -
Date:
VERIFICATION OF BOHR’S ATOMIC ORBITAL THEORY WORKING FORMULA
In 1914, James Franck and Gustav Hertz performed an experiment which demonstrated the existence of excited states in mercury atoms, helping to confirm the quantum theory which predicted that electrons occupied only discrete, quantized energy states. Electrons were accelerated by a voltage toward a positively charged grid in a glass envelope filled with mercury vapor. Past the grid was a collection plate held at a small negative voltage with respect to the grid. The values of accelerating voltage where the current dropped gave a measure of the energy necessary to force an electron to an excited state.
Procedure & Results: 1. Turn on the system after confirming that all control knows is in their minimum position. 2. Turn on the ‘manual/ auto’ switch to manual 3. Turn the voltage display sector to and adjust the V G1k control knob to 1.5V. 4. Selecting the appropriate display set V G2k to 7.5V. 5. Change the value of V G2k in small steps and record the current reading. VG1k = 1.5V, VG2k = 7.5V
VG2k in volts
Plate current (I) X10- in amp
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RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
6. Draw graph showing the variation of current as a function of accelerating voltage. 7. Turn the ‘manual/ auto’ switch to auto. 8. Connect the instrument’s Y, G, X sockets to the corresponding ports of the oscilloscope. Set the oscilloscope to x-y mode and the trigger to external x. 9. Adjust the shift and the gain switches to obtain a clear waveform. Apply the maximum scan range through the instrument. To measure the excitation potential from the CRO - NA No. Distance between the Gain factor Excitation potential of peaks (volts/div) g ng (eV) obs (no. of divisions) n
Average excitation potential (eV)
10. Measure the average horizontal distance between the peaks. This would give the value of Argon atom’s first excitation potential in eV.
To measure the excitation potential from the graph No. of Distance between peaks Average distance Obs to peaks (V) between peaks to peaks (V) 1 2 – 1 = 2 3 – 2 = 3 4 – 3 = 4 5 – 4 = 5 6 – 5 = 6 7 – 6
Average excitation potential (eV)
Viva voce questions
1. What is the use of setting V G1K at 1.5 volts?
It is used to accelerate the electrons emitted from cathode towards anode. 2. What is the use of setting V G2A at 7.5 volts?
This grid acts as a sort of retarding potential for the electrons if the electrons have more than 7.5 volts then they will pass and reach anode and we will get current otherwise they will return and then re-accelerate towards anode. 3. What is used to fill the glass tube? Name its suitable replacement.
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RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
It is filled with mercury vapors because they don’t react with free electrons any inert gas can
be its suitable example.e.g-neon,argon etc. 4. What kind of collision occurs in between electrons and mercury vapors?
Both elastic and inelastic collision occurs.During elastic collision electrons gain energy while during inelastic collision they give all their energy to mercury vapors. 5. How do we prove the existence o f discreet energy levels?
As long as the collision between electrons and mercury vapors is elastic the electron will gain energy but after a certain time it reaches a thresh hold and it gains enough energy to ionize Hg vapors by inelastic collision.Thus,it loses its energy and jumps in the immediate next energy level i.e s,p,d,f. When plotting graph it is seen that after an inelastic collision the graph falls rather abruptly but it should also be noted that every time the graph falls its value will always be greater than the previous fall this along with the rather haphazard way the graph gets plotted contributes to the idea that electrons exist at different energy levels. 6. What do you man by Discreet energy levels?
A quantum mechanical system or particle that is bound — that is, confined spatially — can only take on certain discrete values of energy. This contrasts with classical particles, which can have any energy. These discrete values are called energy levels. It means that atoms can have only certain definite amount of energy state as light is emitted and absorbed by atoms. 7. What is Bohr’s theory? A.Bohr’s theory states that elec trons orbiting nucleus can exist only in certain energy levels.
A jump from one energy level to another is usually accompanied by absorption or emission of a quantum of radiation.
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RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
Expt. No. -
Date:
TO DETERMINE THE DIELECTRIC CONSTANT OF A CAPACITOR WORKING FORMULA
The capacitance of a parallel plate capacitor having air between the plate is given by C o = 0A/d (in F) where 0 = permittivity of air = 10 9/36, A = Area of each plates of parallel capacitor = r 2, d = distance between parallel plates. When the dielectric material is introduced between two gold-plated brass discs of a parallel plate capacitor, it is found that the capacitance increase by a factor 1 which is the relative permittivity/ dielectric constant of the material. It is the ratio of actual permittivity of the medium to that of air. Now Co = r 2 / (36d 109) = r 2 / 36d nF Where r represents the radius of gold-plated brass disc and d represents the thickness of the sample. Then 1 = CT/Co where Co represents the capacitance of dielectric cell with the plates separated by air whose thickness is the same as the thickness of the sample material and C T represents the capacitance with sample. ATTN () = Attenuation constant INT = Integrator with R = 680 K and T = 1/F F1 = 1.47 KHz, F2 = 0.76 KHz, F3 = 0.53 KHz α = 1/11, Ri = 680 KΩ, Vs(PP) = 20 V
Procedure & Results: 1. Find the vernier constant of Slide Callipers 2. Find the thickness of each material (Teflon, Bakelite, Plywood, Rubber and Glass) Material M.S.R. (cm) V.S.R.(cm) Average Average Thickness(m) Thickness(cm)
3. Measure the circumference of the material and from this find out the radius of the material in meter unit (Circumference = 2r) 4. Find Co each of the material.
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RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
5. Insert each of the material inside the parallel plate capacitor. Take Vs(pp) = 20 V. For each frequency find out the Vo(p). Material 1.
Frequency (kHz) F1 F2 F3 F1 F2 F3 F1 F2 F3 F1 F2 F3
2. 3. 4.
Vo(p) (volt)
6. Find out CT and find out 1 from the formula
C T
V S ( PP ). .T
8 RiV 0 ( PP )
,
1
C T C 0
Viva voce questions:
1. What is a capacitor?
Capacitor is a device used to store charge. 2. What is meant by capacitance?
Ability to store charge in a capacitor is called capacitance and it is measured in farad, F. 3. What is the relation between Q, C & V?
Q=CV, Q, charge stored(coulomb), C capacitance(farad), V(voltage). 4. Define one farad.
It is the amount of charge required to raise the potential by 1 volt. 5. What is dielectric?
Dielectric is an insulator which is used to increase the capacitance of the capacitor. 6. Classify dielectrics?
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RCC Institute of Information Technology Paper Code: PH 391/491
Sem: odd/even
It is classified into polar and non-polar dielectrics. 7. The dielectric constant depends on what factors?
It depends on frequency, material and temperature. 8. State coulombs law of charges.
It states that force of attraction or repulsion between two charges is directly proportional to the product of the charges and inversely proportional to the square of the distance between them. 9. What is an electric field?
It is the region of space in which a charged body experience force. It is measured in volt per meter. 10. Describe the phasor diagram
for pure resistor, I & V will be in phase, phasor I leads V by 90 degree bur in case of a inductor V lead I by 90 degree. 11. When does the body get charged?
When a body rubbed with another body it gets charged due to loss or gain of electron. 12. What are electric lines of forces?
It is the path travelled by a unit positive charge from positive charge to negative charge.
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