This lecture note
explains the following topics: Hamilton’s Formalism of Classical Physics, State
Vectors and Operators, The Position and Momentum Observables, Quantum Dynamics,
The Harmonic Oscillator, Angular Momentum, Central Potential, Density Operator,
Time Independent Perturbation Theory, Time-Dependent Perturbation Theory, Path
Integration, Adiabatic Approximation, Light Matter Interaction, Open Quantum
Systems.
The contents of the notes include: The Schrodinger equation,
Measurement and uncertainty, The harmonic oscillator, Angular momentum and spin,
Particles in an external magnetic eld, Pictures in quantum mechanics, Particle
in a central potential, Time independent Perturbation theory, Variational
principle, Path integral formulation of quantum mechanics, Scattering Theory.
Author(s): Jorg Schmalian, Karlsruhe Institute
of Technology
This book
explains the following topics: Schrodinger equation, Wronskian theorem, Hilbert
Spaces for Physicists, Postulates of Quantum Mechanics, Harmonic Oscillator in
Operatorial Form, Angular momentum quantization, Symmetries in Quantum
Mechanics, Spin, Identical particles, Hydrogen atom, Time-dependent and
independent perturbation theory, Path integral approach to quantum mechanics, :
Semiclassical quantum mechanics.
This note covers
the following topics: Bound States, Discreet Energy Levels, Electron Diffraction, Exploring
Quantum Tunneling, Uncertainty Principle, Interpreting Wave
Functions, Sketching Wave Functions, Shape of the Wave Function, Wave Packet,
Wave Functions and Energies in Atoms.
This note introduces Quantum Mechanics at an advanced level
addressing students of Physics, Mathematics, Chemistry and Electrical
Engineering. It covers the following topics: Lagrangian Mechanics, Quantum
Mechanical Path Integral, The Schr¨odinger Equation, Linear Harmonic
Oscillator, Theory of Angular Momentum and Spin, Quantum Mechanical Addition
of Angular Momenta and Spin, Motion in Spherically Symmetric Potentials,
Interaction of Charged Particles with Electromagnetic Radiation,
Many–Particle Systems, Relativistic Quantum Mechanics, Spinor Formulation of
Relativistic Quantum Mechanics and Symmetries in Physics.