Vibrational  analysis, Rotational Structure of Electronic bands: General  relations, branches of  a
               band, band-head formation,  Intensity distribution in  a vibrational  band system.  Franck-Condon
               Principle and its wave mechanical formulation.
               UNIT 3                                                                             (15 Hours)

               Lasers:  Temporal  and  spatial  coherence,  shape  and  width  of  spectral  lines,  line  broadening
               mechanism,  natural,  collision  and  Doppler  broadening.  Laser  Pumping  and  Resonators:
               Resonators,  modes  of  a resonator,  number  of  modes  per  unit  volume,  quality  factor,  threshold
               condition.
               Dynamics of the Laser Processes: Rate equations for two, three and four level systems, production
               of a giant pulse – Q switching, mode-locking.
               Types of Lasers: He-Ne gas laser, Nitrogen Laser, CO2 laser, Ruby laser, Semiconductor lasers,
               dye lasers.
               Applications: Holography, non-linear optics: harmonic generation, second harmonic generation,
               phase matching and optical mixing.
                        *
               Tutorial (15 Hours) one hour per week
               SUGGUESTED READINGS:

                   1.  A  Text  book  of  Quantum  Mechanics,  P.M.Mathews  and  K.Venkatesan,  2nd  Ed.,  2010,
                       McGraw Hill
                   2.  Quantum Mechanics, Robert Eisberg and Robert Resnick, 2nd Edn., 2002, Wiley.
                   3.  Quantum Mechanics, Leonard I. Schiff, 3rd Edn. 2010, Tata McGraw Hill.
                   4.  Quantum Mechanics, G. Aruldhas, 2nd Edn. 2002, PHI Learning of India.
                   5.  Quantum Mechanics, Bruce Cameron Reed, 2008, Jones and Bartlett Learning.
                   6.  Quantum Mechanics: Foundations & Applications, Arno Bohm, 3rd Edn., 1993, Springer
                   7.  Quantum  Mechanics  for  Scientists  &  Engineers,  D.A.B.  Miller,  2008,  Cambridge
                       University Press
                   8.  Concepts of Modern Physics, Arthur Beiser, 2009, McGraw-Hill
                   9.  Modern  Physics,  John  R.  Taylor,  Chris  D.  Zafiratos,  Michael  A.Dubson,2009,  PHI
                       Learning
                   10. Six Ideas that Shaped Physics: Particle Behave like Waves, Thomas A. Moore, 2003

               Phys.213                   Quantum Physics                                               3+1*


               LEARNING OBJECTIVES:

               The primary objective of this course is to:
                     Review the basics of quantum mechanics.
                     Formulate time dependent and time independent Schrodinger equations and their solutions
                       with different potentials,
                     Solve applications of quantum mechanics for hydrogen-like and many electron atoms and
                       atoms in electric and magnetic fields

               LEARNING OUTCOMES:

               On successful completion of the module, students should be able to:
                     acquainted with the basic principles of Quantum Mechanics and its applications
                     Have gained a clear knowledge about wave properties of particles, De Broglie waves and
                       its implications on the uncertainty principle.
                     Have grasped the idea of Wave Mechanics and gain the concept of eigen values, eigen
                       functions and learn the basic postulates of quantum mechanics




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