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.
This note
exlains the following topics: electromagnetic waves, Introduction to quantum mechanics, Dynamical
variables and observables in quantum mechanics, Applications, Spin and the pauli
principle, The transition from quantum mechanics to approximate theories and to
molecular dynamics.
This
lecture note explains the following topics: Schrodinger’s Equation, Piecewise
Potentials, Linear Algebra and Function Space, Angular Momentum and Spin,
Multiple Particles, Perturbation Theory – Fine Structure, Time Dependent
Perturbation Theory, Relativistic Quantum Mechanics: The Dirac Equation.
This note describes the following topics: Mathematical Foundations,
Quantum Measurements, Dynamics and Symmetries, Approximation Methods, Quantum
Information Processing, Quantum Information Theory.
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.
The development of quantum
mechanics has taken physics in a vastly new direction from that of classical
physics from the very start. In fact, there continue at present to be many
developments in the subject of a very fundamental nature, such as implications
for the foundations of physics, physics of entanglement, geometric phases,
gravity and cosmology and elementary particles as well. It is hoped the papers
in this volume will provide a much needed resource for researchers with regard
to current topics of research in this growing area.
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.