and  group  aspects.  Spaceinversion  and  time  reversal:  parity  operator  and  anti-linear  operator.
               Dynamical symmetry ofharmonic oscillator.
               Applications: non-relativistic Hamiltonian for an electron with spin included. C. G. coefficients
               of addition for j =1/2, 1/2; 1/2, 1; 1, 1.

               UNIT 3                                                                             (15 Hours)

               Approximation  Methods  for  Bound  State:Time  independent  perturbation  theory  for  non-
               degenerate  and  degenerate  systems  upto  secondorder  perturbation.  Application  to  a  harmonic
               oscillator, first order Stark effect in hydrogenatom, Zeeman effect without electron spin. Variation
               principle, application to ground state ofhelium atom, electron interaction energy and extension of
               variational  principle  to  excited  states.WKB  approximation:  energy  levels  of  a  potential  well,
               quantization  rules.  Time-dependentperturbation  theory;  transition  probability  (Fermi  Golden
               Rule), application to constantperturbation and harmonic perturbation. Semi-classical treatment of
               radiation. Einsteincoefficients; radiative transitions.
               *
                Tutorial(15 Hours) one hour per week

               SUGGESTED READINGS:

                   1.  H. Goldstein, Classical Mechanics 2nd ed. (Indian Student Edition, Addison-Wesley/
                       Narosa).

                   2.  J. B. Marion, Classical Mechanics (Academic Press).
                   3.  L. D. Landau and E. M. Lifshitz, Mechanics 3rd ed. (Pergamon).

               Phys.413                   Statistical Physics                                           3+1*

               LEARNING OBJECTIVES:


               The primary aim of this course is to:
                     provides  an  introduction  to  the  microscopic  formulation  of  thermal  physics,  generally
                       known as statistical mechanics.
                     We  explore  the  general  principles,  from  which  emerge  an  understanding  of  the
                       microscopic significance of entropy and temperature.
                     We develop the machinery needed to form a practical tool linking microscopic models of
                       many-particle systems with measurable quantities.
                     We consider a range of applications to simple models of crystalline solids, classical gases,
                       quantum gases and blackbody radiation.

               LEARNING OUTCOMES:

               After completion of course, students will able to
                     Explain the fundamental principles of statistical physics.
                     Have vast knowledge of thermodynamic quantities.
                     Build knowledge of Gibb‘s distribution and Maxwell distribution.
                     Utilize Gibb‘s distribution for derivation of thermodynamics relations.
                     Grasp the knowledge ideal gases and non-ideal gases and related phenomena and theories.
                     Build the knowledge of quantum statistical  distribution laws:  Bose-Einstein and  Fermi-
                       Dirac and study examples of these distributions.
                     Explain and apply the Phenomenon in very high density systems







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