lecture note explains the following topics: Classical Mechanics, Abstract vector
spaces, Functions as vectors, Postulates of Quantum Mechanics, The Wavefunction,
The Uncertainty Principle, Scattering Theory, Stationary States, Angular
Momentum, The Hydrogen Atom, Spin.
This note explains the following topics:
The Classical State, Historical Origins of Quantum Mechanics, The Wave-like
Behaviour of Electrons, Energy and Uncertainty, Quantum State, Operators and
Observations, Rectangular Potentials, The Harmonic Oscillator, Spectrum of
Angular Momentum, Aspects of Spin, Electron Spin, Approximation Methods, Quantum
Mechanics as Linear Algebra, Feynman Path-Integral Quantization.
This lecture note explains the
following topics: The Early History of Quantum Mechanics, The Wave Function, The
Two Slit Experiment, Wave Mechanics, Particle Spin and the Stern-Gerlach
Experiment, Probability Amplitudes, Vector Spaces in Quantum Mechanics, State
Spaces of Infinite Dimension, Matrix Representations of State Vectors and
Operators, Probability, Expectation Value and Uncertainty, Time Evolution in
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
This note is
intended to teach quantum mechanics to undergraduate students as well as
graduate students. Topics covered includes: Classical Mechanics, Quantum
Mechanics, Time-Dependent Schr¨odinger Equation, Mathematical Preliminarie,
Approximate Methods in Quantum Mechanics, Quantum Mechanics in Crystals, Angular
Momentum, Density Matrix, 2 Quantization of Classical Fields, Schrodinger Wave
Fields, Quantum Information and Quantum Interpretation.
which brought together an international community of invited authors, represents
a rich account of foundation, scientific history of quantum mechanics,
relativistic quantum mechanics and field theory, and different methods to solve
the Schrodinger equation.
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.
note covers the following topics: Special Relativity, Basic Quantum
Mechanics, Single-Particle Systems, Multiple-Particle Systems, Time Evolution,
Basic and Quantum Thermodynamics, Angular momentum and Electromagnetism.
This book covers the following topics: Maxwell’s Equations, Electrostatic Fields, Potential Theory, Magnetostatic
Fields, Magnetostatics in Magnetic Media, Wave Propagation in Uniform
Dielectric Media, Wave Propagation in Inhomogeneous Dielectric Media,
Radiation and Scattering, Resonant Cavities and Waveguides, Multipole
Expansion, Relativity and Electromagnetism.