![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 1
I B.Tech Regular Examinations, May/Jun 2008
APPLIED PHYSICS
( Common to Electrical & Electronic Engineering, Electronics &
Communication Engineering, Computer Science & Engineering, Electronics
& Instrumentation Engineering, Bio-Medical Engineering, Information
Technology, Electronics & Control Engineering, Computer Science &
Systems Engineering, Electronics & Telematics, Electronics & Computer
Engineering and Instrumentation & Control Engineering)
Time: 3 hours Max Marks: 80
Answer any FIVE Questions
All Questions carry equal marks
1. (a) Explain the forces between the two interacting atoms when they are brought
nearer to form a molecule.
(b) Derive the expression for the equilibrium spacing of two atoms for which the
potential energy is minimum. [6+10]
2. (a) Explain de-Broglie hypothesis.
(b) Describe G.P.Thomson’s experiment in support of this hypothesis.
(c) Find the wavelength associated with an electron rose to a potential 1600 V.
[4+8+4]
3. (a) Distinguish between Drude-Lorentz theory and Sommerfeld’s theory of metals.
(b) De ne Fermi level of electron.
(c) Find the drift velocity of free electrons in a copper wire of cross-sectional area
10 mm2, when the wire carries a current of 100 A. Assume that each copper
atom contributes one electron to the electron gas. [Density of copper = 8.92
× 103 kg/m3, Atomic weight of copper = 63.5 and Avogadro’s number = 6.02
× 1026 per k-mol] [10+2+4]
4. (a) Explain the following:
i. Dielectric constant
ii. Electric susceptibility,
iii. Electric Polarization and
iv. Polarizability.
(b) Write notes on:
i. Ferro-electricity and
ii. Piezo-electricity. [6+10]
5. (a) Explain the critical parameters and their signi cance in superconductors.
(b) Write notes on:](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-1-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 1
ii. energy gap, in superconductors.
(c) A Josephson junction having a voltage of 8.50 V across its terminals, then
calculate the frequency of the alternating current. [Planck’s constant = 6.626
×10-34 J-sec] [4+8+4]
6. (a) Explain the characteristics of a LASER.
(b) Describe the construction and working of Ruby laser.
(c) Write any four applications of laser. [4+8+4]
7. (a) Derive an expression for the ‘numerical aperture’ of an optical ber.
(b) Explain the advantages of optical communication system.
(c) The numerical aperture of an optical ber is 0.39. If the di erence in the
refractive indices of the material of its core and the cladding is 0.05, calculate
the refractive index of material of the core, when the light is launched into it
in air. [8+4+4]
8. (a) Write a detailed note on nanoscience and nanotechnology.
(b) Write the important applications of nanomaterials in medicine. [10+6]](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-2-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 2
I B.Tech Regular Examinations, May/Jun 2008
APPLIED PHYSICS
( Common to Electrical & Electronic Engineering, Electronics &
Communication Engineering, Computer Science & Engineering, Electronics
& Instrumentation Engineering, Bio-Medical Engineering, Information
Technology, Electronics & Control Engineering, Computer Science &
Systems Engineering, Electronics & Telematics, Electronics & Computer
Engineering and Instrumentation & Control Engineering)
Time: 3 hours Max Marks: 80
Answer any FIVE Questions
All Questions carry equal marks
1. (a) What is Bragg’s law? Explain.
(b) Describe Laue’s metho d for the determination of crystal structure.
(c) The Bragg’s angle in the rst order for (2 2 0) re ection from nickel (FCC) is
38.20 when X-rays of wavelength 1.54 ° A are employed in a di raction experi-
ment. Determine the lattice parameter of nickel. [4+8+4]
2. (a) Explain, in detail, the properties of matter waves.
(b) Describe Davisson and Germer experiment to verify the wave nature of matter.
[6+10]
3. (a) Distinguish between classical free electron theory and quantum free electron
theory of metals.
(b) Explain the Fermi-Dirac distribution function of electrons. Explain the e ect
of temperature on the distribution. [8+8]
4. (a) Explain the following:
i. Dielectric constant
ii. Electric susceptibility,
iii. Electric Polarization and
iv. Polarizability.
(b) Write notes on:
i. Ferro-electricity and
ii. Piezo-electricity. [6+10]
5. (a) What is Meissner e ect? Explain.
(b) Describe the di erence between Type-I and Type-II superconductors.
(c) The critical eld for niobium is 1 × 105 amp/m at 8 K and 2 × 105 amp/m
at absolute zero. Find the transition temperature of the element. [4+8+4]
6. (a) Distinguish between spontaneous emission and stimulated emission](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-3-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 2
(b) Distinguish between homo-junction semiconductor laser and hetero-junction
semiconductor laser.
(c) A semiconductor diode laser has a peak emission wavelength of 1.55 m. Find
its band gap in eV. [4+8+4]
7. (a) Derive the expressions for
i. acceptance angle and
ii. numerical aperture, of an optical ber.
(b) Describe di erent types of bers by giving the refractive index pro les and
propagation details. [8+8]
8. (a) How the physical and chemical properties of nano-particles vary with their
size?
(b) Write the important applications of nanomaterials. [10+6]](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-4-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 3
I B.Tech Regular Examinations, May/Jun 2008
APPLIED PHYSICS
( Common to Electrical & Electronic Engineering, Electronics &
Communication Engineering, Computer Science & Engineering, Electronics
& Instrumentation Engineering, Bio-Medical Engineering, Information
Technology, Electronics & Control Engineering, Computer Science &
Systems Engineering, Electronics & Telematics, Electronics & Computer
Engineering and Instrumentation & Control Engineering)
Time: 3 hours Max Marks: 80
Answer any FIVE Questions
All Questions carry equal marks
1. (a) Plot and explain the variation of (i) attractive potential energy (ii) repulsive
potential energy and (iii) resultant potential energy with inter-atomic distance,
when two atoms are brought nearer.
(b) The Madelung constant of KCl is 1.75. Its neighbour separation is 0.314 nm.
Find the cohesive energy per atom. [Given that the Repulsive exponent value
= 5.77; Ionization energy of potassium = 4.1 eV; Electron a nity of chlorine
= 3.6 eV] [10+6]
2. (a) Discuss the de Broglie hypothesis of duality of matter particles.
(b) Describe GP Thomsons experiment to verify the wave nature of matter.[6+10]
3. (a) Explain the terms (i) mean free path, (ii) relaxation time and (iii) drift velocity
of an electron in a metal.
(b) Discuss the origin of electrical resistance in metals.
(c) Calculate the mobility of the electrons in copper obeying classical laws. Given
that the density of copper = 8.92 × 103 kg/m3, Resistivity of copper = 1.73
×10-8 ohm-m, atomic weight of copper = 63.5 and Avogadro’s number = 6.02
×1026 per k-mol. [6+6+4]
4. (a) Describe the phenomenon of electronic polarization and obtain an expression
for electronic polarizability.
(b) Write notes on:
i. Ferro-electricity and
ii. Piezo-electricity. [8+8]
5. (a) Write a note on intrinsic semiconductors.
(b) Derive an expression for the carrier concentration in n-type extrinsic semi-
conductors. [6+10]
6. (a) Distinguish between spontaneous emission and stimulated emission..
(b) Distinguish between homo-junction semiconductor laser and hetero-junction](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-5-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 3
(c) Calculate the wavelength of emitted radiation from GaAs which has a band
gap of 1.44 eV. [4+8+4]
7. (a) What are important features of optical bers?
(b) Describe the communication process using optical bers.
(c) Write the uses of ber optics in di erent elds. [4+6+6]
8. (a) Write a detailed note on nanoscience and nanotechnology.
(b) Write the important applications of nanomaterials in medicine. [10+6]](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-6-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 4
I B.Tech Regular Examinations, May/Jun 2008
APPLIED PHYSICS
( Common to Electrical & Electronic Engineering, Electronics &
Communication Engineering, Computer Science & Engineering, Electronics
& Instrumentation Engineering, Bio-Medical Engineering, Information
Technology, Electronics & Control Engineering, Computer Science &
Systems Engineering, Electronics & Telematics, Electronics & Computer
Engineering and Instrumentation & Control Engineering)
Time: 3 hours Max Marks: 80
Answer any FIVE Questions
All Questions carry equal marks
1. (a) Explain the various types of bonding in solids with suitable examples.
(b) The Madelung constant of KCl is 1.75. Its neighbour separation is 0.314 nm.
Find the cohesive energy per atom. [Given that the Repulsive exponent value
= 5.77; Ionization energy of potassium = 4.1 eV; Electron a nity of chlorine
= 3.6 eV] [10+6]
2. (a) Distinguish between a matter wave and an electromagnetic wave.
(b) Describe GP Thomson’s experiment to study electron di raction.
(c) Find the wavelength associated with an electron rose to a potential 1600 V.
[4+8+4]
3. (a) Explain the following:
i. Electrical resistivity and
ii. Fermi energy.
(b) Explain brie y the quantum free electron theory of metals.
(c) On the basis of band theory how the crystalline solids are classi ed into metals,
semiconductors and insulators? [4+6+6]
4. (a) Explain the hysteresis loop observed in Ferro-magnetic materials.
(b) Explain clearly di erence between hard and soft magnetic materials. [8+8]
5. (a) How are ‘superconductors’ classi ed? Explain their properties.
(b) What is Meissner e ect? Explain.
(c) Write notes on the applications of superconducting materials. [6+4+6]
6. (a) Describe the various metho ds to achieve population inversion relating to lasers.
(b) With the help of a suitable diagram, explain the principle, construction and
working of a semiconductor laser. [6+10]
7. (a) Distinguish between light propagation in](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-7-320.jpg)
![www.studentyogi.com www.studentyogi.com
Code No: 07A1BS05
Set No. 4
ii. graded index optical ber.
(b) Write a note on ber optic medical endoscopy. [10+6]
8. (a) Write a detailed note on nanoscience.
(b) Why nanomaterials exhibit di erent properties? Explain. [6+10]](https://image.slidesharecdn.com/applied-physics-jntu-btech-2008jntumodelpaperwww-studentyogi-com-100114004702-phpapp01/85/Applied-Physics-Jntu-Btech-2008-Jntu-Model-Paper-Www-Studentyogi-Com-8-320.jpg)
Applied Physics Jntu Btech 2008 Jntu Model Paper{Www.Studentyogi.Com}
- 1. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 1 I B.Tech Regular Examinations, May/Jun 2008 APPLIED PHYSICS ( Common to Electrical & Electronic Engineering, Electronics & Communication Engineering, Computer Science & Engineering, Electronics & Instrumentation Engineering, Bio-Medical Engineering, Information Technology, Electronics & Control Engineering, Computer Science & Systems Engineering, Electronics & Telematics, Electronics & Computer Engineering and Instrumentation & Control Engineering) Time: 3 hours Max Marks: 80 Answer any FIVE Questions All Questions carry equal marks 1. (a) Explain the forces between the two interacting atoms when they are brought nearer to form a molecule. (b) Derive the expression for the equilibrium spacing of two atoms for which the potential energy is minimum. [6+10] 2. (a) Explain de-Broglie hypothesis. (b) Describe G.P.Thomson’s experiment in support of this hypothesis. (c) Find the wavelength associated with an electron rose to a potential 1600 V. [4+8+4] 3. (a) Distinguish between Drude-Lorentz theory and Sommerfeld’s theory of metals. (b) De ne Fermi level of electron. (c) Find the drift velocity of free electrons in a copper wire of cross-sectional area 10 mm2, when the wire carries a current of 100 A. Assume that each copper atom contributes one electron to the electron gas. [Density of copper = 8.92 × 103 kg/m3, Atomic weight of copper = 63.5 and Avogadro’s number = 6.02 × 1026 per k-mol] [10+2+4] 4. (a) Explain the following: i. Dielectric constant ii. Electric susceptibility, iii. Electric Polarization and iv. Polarizability. (b) Write notes on: i. Ferro-electricity and ii. Piezo-electricity. [6+10] 5. (a) Explain the critical parameters and their signi cance in superconductors. (b) Write notes on:
- 2. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 1 ii. energy gap, in superconductors. (c) A Josephson junction having a voltage of 8.50 V across its terminals, then calculate the frequency of the alternating current. [Planck’s constant = 6.626 ×10-34 J-sec] [4+8+4] 6. (a) Explain the characteristics of a LASER. (b) Describe the construction and working of Ruby laser. (c) Write any four applications of laser. [4+8+4] 7. (a) Derive an expression for the ‘numerical aperture’ of an optical ber. (b) Explain the advantages of optical communication system. (c) The numerical aperture of an optical ber is 0.39. If the di erence in the refractive indices of the material of its core and the cladding is 0.05, calculate the refractive index of material of the core, when the light is launched into it in air. [8+4+4] 8. (a) Write a detailed note on nanoscience and nanotechnology. (b) Write the important applications of nanomaterials in medicine. [10+6]
- 3. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 2 I B.Tech Regular Examinations, May/Jun 2008 APPLIED PHYSICS ( Common to Electrical & Electronic Engineering, Electronics & Communication Engineering, Computer Science & Engineering, Electronics & Instrumentation Engineering, Bio-Medical Engineering, Information Technology, Electronics & Control Engineering, Computer Science & Systems Engineering, Electronics & Telematics, Electronics & Computer Engineering and Instrumentation & Control Engineering) Time: 3 hours Max Marks: 80 Answer any FIVE Questions All Questions carry equal marks 1. (a) What is Bragg’s law? Explain. (b) Describe Laue’s metho d for the determination of crystal structure. (c) The Bragg’s angle in the rst order for (2 2 0) re ection from nickel (FCC) is 38.20 when X-rays of wavelength 1.54 ° A are employed in a di raction experi- ment. Determine the lattice parameter of nickel. [4+8+4] 2. (a) Explain, in detail, the properties of matter waves. (b) Describe Davisson and Germer experiment to verify the wave nature of matter. [6+10] 3. (a) Distinguish between classical free electron theory and quantum free electron theory of metals. (b) Explain the Fermi-Dirac distribution function of electrons. Explain the e ect of temperature on the distribution. [8+8] 4. (a) Explain the following: i. Dielectric constant ii. Electric susceptibility, iii. Electric Polarization and iv. Polarizability. (b) Write notes on: i. Ferro-electricity and ii. Piezo-electricity. [6+10] 5. (a) What is Meissner e ect? Explain. (b) Describe the di erence between Type-I and Type-II superconductors. (c) The critical eld for niobium is 1 × 105 amp/m at 8 K and 2 × 105 amp/m at absolute zero. Find the transition temperature of the element. [4+8+4] 6. (a) Distinguish between spontaneous emission and stimulated emission
- 4. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 2 (b) Distinguish between homo-junction semiconductor laser and hetero-junction semiconductor laser. (c) A semiconductor diode laser has a peak emission wavelength of 1.55 m. Find its band gap in eV. [4+8+4] 7. (a) Derive the expressions for i. acceptance angle and ii. numerical aperture, of an optical ber. (b) Describe di erent types of bers by giving the refractive index pro les and propagation details. [8+8] 8. (a) How the physical and chemical properties of nano-particles vary with their size? (b) Write the important applications of nanomaterials. [10+6]
- 5. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 3 I B.Tech Regular Examinations, May/Jun 2008 APPLIED PHYSICS ( Common to Electrical & Electronic Engineering, Electronics & Communication Engineering, Computer Science & Engineering, Electronics & Instrumentation Engineering, Bio-Medical Engineering, Information Technology, Electronics & Control Engineering, Computer Science & Systems Engineering, Electronics & Telematics, Electronics & Computer Engineering and Instrumentation & Control Engineering) Time: 3 hours Max Marks: 80 Answer any FIVE Questions All Questions carry equal marks 1. (a) Plot and explain the variation of (i) attractive potential energy (ii) repulsive potential energy and (iii) resultant potential energy with inter-atomic distance, when two atoms are brought nearer. (b) The Madelung constant of KCl is 1.75. Its neighbour separation is 0.314 nm. Find the cohesive energy per atom. [Given that the Repulsive exponent value = 5.77; Ionization energy of potassium = 4.1 eV; Electron a nity of chlorine = 3.6 eV] [10+6] 2. (a) Discuss the de Broglie hypothesis of duality of matter particles. (b) Describe GP Thomsons experiment to verify the wave nature of matter.[6+10] 3. (a) Explain the terms (i) mean free path, (ii) relaxation time and (iii) drift velocity of an electron in a metal. (b) Discuss the origin of electrical resistance in metals. (c) Calculate the mobility of the electrons in copper obeying classical laws. Given that the density of copper = 8.92 × 103 kg/m3, Resistivity of copper = 1.73 ×10-8 ohm-m, atomic weight of copper = 63.5 and Avogadro’s number = 6.02 ×1026 per k-mol. [6+6+4] 4. (a) Describe the phenomenon of electronic polarization and obtain an expression for electronic polarizability. (b) Write notes on: i. Ferro-electricity and ii. Piezo-electricity. [8+8] 5. (a) Write a note on intrinsic semiconductors. (b) Derive an expression for the carrier concentration in n-type extrinsic semi- conductors. [6+10] 6. (a) Distinguish between spontaneous emission and stimulated emission.. (b) Distinguish between homo-junction semiconductor laser and hetero-junction
- 6. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 3 (c) Calculate the wavelength of emitted radiation from GaAs which has a band gap of 1.44 eV. [4+8+4] 7. (a) What are important features of optical bers? (b) Describe the communication process using optical bers. (c) Write the uses of ber optics in di erent elds. [4+6+6] 8. (a) Write a detailed note on nanoscience and nanotechnology. (b) Write the important applications of nanomaterials in medicine. [10+6]
- 7. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 4 I B.Tech Regular Examinations, May/Jun 2008 APPLIED PHYSICS ( Common to Electrical & Electronic Engineering, Electronics & Communication Engineering, Computer Science & Engineering, Electronics & Instrumentation Engineering, Bio-Medical Engineering, Information Technology, Electronics & Control Engineering, Computer Science & Systems Engineering, Electronics & Telematics, Electronics & Computer Engineering and Instrumentation & Control Engineering) Time: 3 hours Max Marks: 80 Answer any FIVE Questions All Questions carry equal marks 1. (a) Explain the various types of bonding in solids with suitable examples. (b) The Madelung constant of KCl is 1.75. Its neighbour separation is 0.314 nm. Find the cohesive energy per atom. [Given that the Repulsive exponent value = 5.77; Ionization energy of potassium = 4.1 eV; Electron a nity of chlorine = 3.6 eV] [10+6] 2. (a) Distinguish between a matter wave and an electromagnetic wave. (b) Describe GP Thomson’s experiment to study electron di raction. (c) Find the wavelength associated with an electron rose to a potential 1600 V. [4+8+4] 3. (a) Explain the following: i. Electrical resistivity and ii. Fermi energy. (b) Explain brie y the quantum free electron theory of metals. (c) On the basis of band theory how the crystalline solids are classi ed into metals, semiconductors and insulators? [4+6+6] 4. (a) Explain the hysteresis loop observed in Ferro-magnetic materials. (b) Explain clearly di erence between hard and soft magnetic materials. [8+8] 5. (a) How are ‘superconductors’ classi ed? Explain their properties. (b) What is Meissner e ect? Explain. (c) Write notes on the applications of superconducting materials. [6+4+6] 6. (a) Describe the various metho ds to achieve population inversion relating to lasers. (b) With the help of a suitable diagram, explain the principle, construction and working of a semiconductor laser. [6+10] 7. (a) Distinguish between light propagation in
- 8. www.studentyogi.com www.studentyogi.com Code No: 07A1BS05 Set No. 4 ii. graded index optical ber. (b) Write a note on ber optic medical endoscopy. [10+6] 8. (a) Write a detailed note on nanoscience. (b) Why nanomaterials exhibit di erent properties? Explain. [6+10]