Course |
Learning outcome (at course level) |
Learning and teaching strategies |
Assessment Strategies |
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Paper Code |
Paper Title |
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PHY 423 |
Advanced Quantum Mechanics
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After the completion of this course the student will be able to: CO 135: Describe the basic Hilbert space structures describing all quantum field theories.
CO 136: explain the relativistic quantum mechanical equations, namely, Klein-Gordon equation and Dirac equation.
CO 137: Knowledge of interaction of Bosons and Fermions particles .
CO 138: describe second quantization and related concepts.
CO 139: Explain the formalism of relativistic quantum field theory.
CO 140: draw and explain Feynman graphs for different interactions.
CO 141: Model physical systems using common approximation techniques for making dynamical calculations.
CO 142: Critically analyse probability current density for a fully defined quantum theory.
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Approach in teaching: Interactive Lectures, Discussion, Tutorials, , Demonstration, Problem Solving in tutorials
Learning activities for the students: Self learning assignments, Effective questions, Seminar presentation, Solving numerical. Additional learning through online videos and MOOC courses |
Class test, Semester end examinations, Quiz, Solving problems, Assignments, Presentations |
Differential and total scattering cross section, transformation from CM frame to Lab frame, solution of scattering problem by the method of partial wave analysis, expansion of a plane wave into a spherical wave and scattering amplitude, the optical theorem, Applications: scattering from a delta potential, square well potential and the hard sphere scattering of identical particles, energy dependence and resonance scattering, Breit-Wigner formula, quasi stationary states, Lippman-Schwinger equation and the Green's functions approach for scattering problem, Born approximation and its validity for scattering problem, Coulomb scattering problem under first Born approximation in elastic scattering.
Attempt for relativistic formulation of quantum theory, The Klein-Gordon equation, Probability density and probability current density, solution of free particle KG equation in momentum representation, interpretation of negative probability density and negative energy solutions.
Properties of Dirac matrices and algebra of gamma matrices, non-relativistic correspondence of the Pauli equation (inclusive of electromagnetic interaction), Solution of free particle Dirac equation, orthogonality and completeness, relations for Dirac spinors, interpretation of negative energy solution, Lorentz covariance of Dirac equation, charge conjugation (C), Parity(P), time reversal (T) , CPT theorem, Zitterbewegung.
Classical radiation field, transversality condition, Fourier decomposition and radiation oscillators, Quantization of radiation oscillator, creation, annihilation and number operators, photon states, photon as a quantum mechanical excitations of the radiation field, fluctuations and the uncertainty relation, validity of the classical description, matrix element for emission and absorption, spontaneous emission in the dipole approximation, Rayleigh scattering. Thomson scattering and the Raman effect, Radiation damping and Resonance fluorescence.
S-matrix, S-matrix expansion, Wick's theorem, Diagrammatic representation in configuration space, the momentum representation, Feynman diagrams of basic processes. Applications of S-matrix formalism: The Coulomb scattering, Bhabha scattering, Compton scattering and Pair production