Goal: This course is a deepening of the quantum mechanics concepts introduced in the undergraduate courses. The fundamental principle of quantum mechanics are illustrated by applications to nanoscale condensed-matter systems taken from recent research works and by discussing prospects for quantum information technologies. The concepts presented in this course are prerequisites for many second-year courses related to nanophysics and quantum engineering. A good knowledge in quantum mechanics is indeed more and more essential for technological research and development of nanoscale quantum devices.
Content
Chapter 1: Introduction and recalls on the quantum mechanics postulates and formalism (Dirac notation, Hilbert space). Two-level system, Zeeman effect, spin Hamiltonian. Tensorial product notation for states and operators. Many-body quantum states (bosons and fermions).
Exercices: Basics of quantum mechanics formalism.
Chapter 2: Recalls on confinement problem. Electron bound states in a potential.
Exercises: Example of 1D confinement problems, quantum harmonic oscillator.
Chapter 3: Introduction to atomic physics. Spherical symmetry, angular and spin kinetic momenta. Mean field approximation, central potential, many electrons atoms, Hund rules, spin-orbit coupling, optical transitions.
Exercises: Grotrian diagrams, spin-orbit coupling, fine and hyperfine structure.
Chapter 4: Approximation methods for eigenstate calculations, perturbation theory, variational method.
Exercises: Application to electronic systems.
Chapter 5: Time evolution. General equation for the time evolution, two-level systems, perturbation theory, Fermi golden rules.
Exercises: Application to Rabi oscillations.
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