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.
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 note describes the following topics: Mathematical Foundations,
Quantum Measurements, Dynamics and Symmetries, Approximation Methods, Quantum
Information Processing, Quantum Information Theory.
This book,
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 notes contains the details about
Heisenberg's road to the uncertainty relations,
Heisenberg's argument, The
interpretation of Heisenberg's relation, Bohr and
The Minimal Interpretation
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 covers the following topics: Introduction to Superposition,
Experimental Facts of Life, The Wave Function, Expectations, Momentum, and
Uncertainty , Operators and the Schrödinger Equation, Time Evolution and the
Schrödinger Equation, Energy Eigenstates and Quantum Harmonic Oscillator.
Author(s): Prof. Allan Adams, Prof. Matthew Evans and Prof. Barton
Zwiebach