*
                Tutorial(15 Hours) one hour per week

               SUGGUESTED READINGS:

                  1.  Molecular Symmetry, D. J. Willock (John Wiley & Sons, 2009)
                  2.  Molecular Spectra and Molecular Structure, G. Herzberg (Van Nostrand, 1950)
                  3.  Group Theory and Physics, S. Sternberg (Cambridge Univ. Press, 1995)
                  4.  Modern Spectroscopy, J. M. Hollas( 4th Ed., John Wiley, 2004)
                  5.  Molecular Quantum Mechanics, P Atkins & R. Friedman (Oxford Univ. Press, 2005)
                  6.  Molecular Physics, W. Demtroder (Wiley-VCH, 2005)
                  7.  Laser Spectroscopy, W. Demtroder (3rd Ed., Springer, 2003)
                  8.  Physics  of  Atoms  and  Molecules,  B.  H.  Bransden  and  C.  J.  Joachain,  2nd  Ed.  Pearson
                      (2008).
                  9.  Fundamentals of Molecular Spectroscopy, C. N. Banwell and E. M. McCash, 4th Ed.,Tata
                      McGraw 2004.
                  10. Elementary Atomic Structure, G. K. Woodgate, Clarendon Press 1989.
                  11. Quantum Chemistry, I. N. Levine, PHI 2009.
                  12. Elementary Quantum Chemistry, F. L. Pilar, McGraw Hill 1990.
                  13. Essentials of Lasers and Non-Linear Optics,G.D. Baruach, Ist Ed. Pragati Prakashan, 2000.
                  14. Lasers and Non-Linear Optics- B.B. Laud, 2nd Ed., New age International (P) Ltd. 1996.
                  15. Introduction to Atomic Spectra, H. E. White, Tata McGraw Hill 1934.
                  16. Principles of Laser, O. Svelto, 4th Ed. ,Springer , 2008

               Phys.424                   Nano Physics                                                  3+1*


               LEARNING OBJECTIVES:

               The primary aim of this course is to:
                     introduce knowledge on basics of nanoscience and the fundamental concepts behind size
                       reduction in various physical properties.
                     More  specifically,  the  student  will  be  able  to  understand  the  different  properties  of
                       materials in reduced scales.
                     aware and teach about nanomaterials, their different synthesis methods, their properties,
                       introduction with special carbon and their application in various fields.



               LEARNING OUTCOMES:

               After completion of course, students will able to:
                     Realize  the  impact  of  development  of  nanomaterials  in  everyday  life  such  as  in
                       nanoelectronics,  energy  sector,  automobile,  defense,  space,  medical  field,  several  other
                       industries, and future perspectives
                     Understand the concepts of bulk and quantum nanostructures.
                     Familiar  with  basic  theoretical  modeling  of  nanostructured  materials  and  prediction  of
                       their properties.
                     Understand the concept of using natural occurring materials as templates for synthesizing
                       nanomaterials.
                     Realize the influence of one, two and three dimensional confinements on electronic and
                       other properties of nanostructured materials.
                     Will be able to describe different type of nanomaterials and their size and dimensionality
                       effect. Also





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