Digital Teaching
Lectures and exercises are held in person in compliance with hygiene guidelines. In the case of a dynamic pandemic situation, it may be necessary to hold the classes online. In this case, the access data for the event will be announced via Moodle, which is used to organize lectures and exercises.
Course Contents
[list=1]
[*]Axiomatic Structure of Quantum Mechanics
[*]Perturbative Methods
[*]Scattering Theory
[*]Path Integrals
[*]Relativistic Wave Equations
[*]Many-particle Theory
[/list]
Literature
[list]
[*]J. J. Sakurai and J. Napolitano, Modern Quantum Mechanics, Pearson
[*]J. J. Sakurai, Advanced Quantum Mechanics, Pearson
[*]F. Schwabl, Quantenmechanik (QM I), Springer
[*]F. Schwabl, Quantenmechanik für Fortgeschrittene (QM II), Springer
[*]G. Münster, Quantentheorie, de Gruyter
[*]D. A. Steck, Quantum Mechnics
[*]J. R. Taylor, Scattering Theory: The Quantum Theory on Nonrelativistic Collisions, Wiley
[*]H. Kleinert, Path Integrals in Quantum Mechanics, Statistics, Polymer Physics, and Financial Markets, World Scientific Publ.
[/list]
Preconditions
Basic knowledge in theory classes of Bachelor's programm classes, in particular Quantum Mechanics is helpful
Further Grading Information
Exercises will be organized via Moodle.
Official Course Description
Quantum physics is an essential building block of our modern worldview and of relevance to many subfields of physics. The lecture "Höhere Quantenmechanik" complements the basic knowledge in quantum mechanics gained in previous lectures and paves the way to apply quantum theory in current and state-of-the-art research. The focus of this lecture lies on on approximation methods, elements of many-particle theories, and relativistic approaches to a description of quantum particles and processes.
Online Offerings
moodle
Lectures and exercises are held in person in compliance with hygiene guidelines. In the case of a dynamic pandemic situation, it may be necessary to hold the classes online. In this case, the access data for the event will be announced via Moodle, which is used to organize lectures and exercises.
Course Contents
[list=1]
[*]Axiomatic Structure of Quantum Mechanics
[*]Perturbative Methods
[*]Scattering Theory
[*]Path Integrals
[*]Relativistic Wave Equations
[*]Many-particle Theory
[/list]
Literature
[list]
[*]J. J. Sakurai and J. Napolitano, Modern Quantum Mechanics, Pearson
[*]J. J. Sakurai, Advanced Quantum Mechanics, Pearson
[*]F. Schwabl, Quantenmechanik (QM I), Springer
[*]F. Schwabl, Quantenmechanik für Fortgeschrittene (QM II), Springer
[*]G. Münster, Quantentheorie, de Gruyter
[*]D. A. Steck, Quantum Mechnics
[*]J. R. Taylor, Scattering Theory: The Quantum Theory on Nonrelativistic Collisions, Wiley
[*]H. Kleinert, Path Integrals in Quantum Mechanics, Statistics, Polymer Physics, and Financial Markets, World Scientific Publ.
[/list]
Preconditions
Basic knowledge in theory classes of Bachelor's programm classes, in particular Quantum Mechanics is helpful
Further Grading Information
Exercises will be organized via Moodle.
Official Course Description
Quantum physics is an essential building block of our modern worldview and of relevance to many subfields of physics. The lecture "Höhere Quantenmechanik" complements the basic knowledge in quantum mechanics gained in previous lectures and paves the way to apply quantum theory in current and state-of-the-art research. The focus of this lecture lies on on approximation methods, elements of many-particle theories, and relativistic approaches to a description of quantum particles and processes.
Online Offerings
moodle
- Lehrende: Enno Giese
Semester: ST 2024