SS 2020:

• A. Hoang: Introduction to Particle Physics
  
  • Lecture Notes, Exercise Sheets and general informations
  • Video lectures

WS 2019

• A. Hoang: Quantenmechanik: Erweiterte Konzepte und Anwendungen
  • Lecture:
    
    • Lecture notes
      • 1 - Principles of Non-Relativistic Quantum Mechanics
      • 2 - Angular Momentum - Part 2
      • 3 - Lagrangian Formalism in Non-relativistic Quantum Mechanics
      • 4 - Scattering Theory
      • 5 - Path Intergral Method
      • 6 - Symmetries in Quantum Mechanics
      • 7 - Klein-Gordon-Equation
      • 8 - Dirac Equation
      • 9 - Hydrogen Fine Structure
      • 10 - Identical particles
  • Exercises:
    • Informations for the exercises and exams
    • Problems:  sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 | sheet 10 | sheet 11 | sheet 12 |
      The links to the exercise sheets will become available on each Thursday.

SS 2019:

• A. Hoang: Theoretische Physik 2 - Quantenmechanik I
  • Lecture:
    
    • Lecture notes (de)
    • Lecture notes (en)
      
      • 1 - Introduction
      • 2 - Elementary Aspects
      • 3 - Problems in One Dimension
      • 4 - Mathematica Structures of Quantum Theory
      • 5 - Particles with Spin 1/2
      • 6 - Spatial Angular Momentum
      • 7 - The Hydrogen Atom
    • QM-1-WaveFunction-Videos.nb
    • Mathematisches Basiswissen für Theoretische Physik T2
    • Sample questions for lecture exam on November 29^th, 2019
  • Exercises:
    • Informations for the exercises and exams
    • Problems:  sheet 1 (sheet-1_ex-4.nb, sheet-1_ex-4.sce) | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 | sheet 10 | sheet 11 | sheet 12 |

• A. Hoang: Praktikum Theoretische Physik
  
  • Produktion von Top-Antitop-Paaren an der Schwelle

• H. Neufeld: Symmetries in Particle Physics
  
  • General informations
  • Lecture notes
    • Chapter 01: Symmetries in classical mechanics and classical field theory
    • Chapter 02: Representation theory of the rotation group
    • Chapter 03: Representation theory of the Lorentz group
    • Chapter 04: Representation theory of the Poincare group
  • Homework problems

WS 2018:

• A. Hoang: Introduction to Particle Physics
  
  • Lecture Notes, Exercise Sheets and general informations
    

• H. Neufeld: Particle Physics 3 - Selected chapters from relativistic quantum field theory
  
  • Lecture notes:
    
    • Chapter 19: Standard model of particle physics
    • Chapter 20: Decay width
    • Chapter 21: Minimal subtraction
    • Chapter 22: Running coupling and running mass
    • Chapter 23: Renormalization group
    • Chapter 24: Functional methods
    • Chapter 25: Background field method
    • Chapter 26: Determinants of differential operators
    • Chapter 27: Chiral anomalies
    • List of exam questions (chapter 19-24)

SS 2018:

• A. Hoang: Quantenmechanik II
  • Lecture:
    
    • Lecture notes
      • 1 - Principles of Non-Relativistic Quantum Mechanics
      • 2 - Scattering Theory
      • 3 - Quantization of the Free Electromagnetic Field
      • 4 - Relativistic Kinematics
      • 5 - Klein-Gordon Equation
      • 6 - Dirac Equation
      • 7 - Quantum Field Theory
      • 8 - Path Integral Method
  • Exercises:
    
    • Problems:  sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 |

• H. Neufeld: Particle physics II
  • Lecture notes:
    • Chapter 01: Introduction
    • Chapter 02: Scalar field
    • Chapter 03: Functional integral
    • Chapter 04: Perturbation theory
    • Chapter 05: Dimensional regularization and renormalization
    • Chapter 06: Renormalizability
    • Chapter 07: Reduction formalism
    • Chapter 08: Cross section
    • Chapter 09: Dirac field
    • Chapter 10: Fermionic path integral
    • Chapter 11: Vector field
    • Chapter 12: Interaction picture
    • Chapter 13: Quantum electrodynamics of spin 1/2 fermions
    • Chapter 14: Anomalous magnetic moments of electron and muon
    • Chapter 15: Nonabelian gauge theories
    • Chapter 16: Quantization of nonabelian gauge fields
    • Chapter 17: Spontaneous symmetry breaking
    • Chapter 18: Spontaneous breaking of local gauge symmetries
    • List of questions for the Lecture Examination (Chapter 1-18)
  • Exercises:
    • Problems 1-56

WS 2017:

• H. Neufeld: Theoretical Physics 3 (Electrodynamics)
  
  • Lecture notes
  • Homework problems

SS 2017:

• A. Hoang: Theoretische Physik 2 - Quantenmechanik I
  • Lecture:
    
    • Lecture notes (ge)
    • Lecture notes (en):
      • 1 - Introduction (170% A4quer)
      • 2 - Elementary Aspects of Quantum Mechanics
      • 2.1-2.6 (170%); 2.7-2.10 (170%)
      • 3 - Problems in One Dimension (170%)
      • 4 - Mathematical Structures of Quantum Theory (170%)
      • 5 - Spin ½ (170%)
      • 6 - Angular Momentum (170%)
      • 7 - The Hydrogen Atom (170%)
      • 8 - Adding Angular Momenta (170%)
      • 9 - Time-Independent Perturbation Theory (170%)
      • 10 - Identical Particles (170%)
    • Mathematisches Basiswissen für Theoretische Physik T2
    • QM-1-WaveFunction-Videos.nb
    • Sample questions for lecture exam ob July 11, 2017
  • Exercises:
    • Informations for the exercises;
    • Problems:  sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7  | sheet 8   | sheet 9 | sheet 10 | sheet 11 |

• H. Neufeld: Particle physics II
  • Lecture notes:
    • Chapter 01: Introduction
    • Chapter 02: Scalar field
    • Chapter 03: Functional integral
    • Chapter 04: Perturbation theory
    • Chapter 05: Dimensional regularization and renormalization
    • Chapter 06: Renormalizability
    • Chapter 07: Reduction formalism
    • Chapter 08: Cross section
    • Chapter 09: Dirac field
    • Chapter 10: Fermionic path integral
    • Chapter 11: Vector field
    • Chapter 12: Interaction picture
    • Chapter 13: Quantum electrodynamics of spin 1/2 fermions
    • Chapter 14: Anomalous magnetic moments of electron and muon
    • Chapter 15: Nonabelian gauge theories
    • Chapter 16: Quantization of nonabelian gauge fields
    • Chapter 17: Spontaneous symmetry breaking
    • Chapter 18: Spontaneous breaking of local gauge symmetries
    • Chapter 19: Standard model of particle physics
    • Chapter 20: Decay Width
    • Chapter 21: Minimal subraction
    • Chapter 22: Running coupling and running mass
    • Chapter 23: Renormalization group
  • List of questions for the lecture exam on particle physics II
  • Exercises:
    • Problems 1-57

SS 2016:

• A. Hoang: Theoretische Physik 2 - Quantenmechanik I
  • Lecture:
    • Lecture notes (ge)
    • Lecture notes (en):
      • 1 - Introduction
      • 2 - Elementary Aspects of Quantum Mechanics
      • 3 - Problems in One Dimension
      • 4 - Mathematical Structures of Quantum Theory
      • 5 - Spin ½
      • 6 - Angular Momentum
      • 7 - The Hydrogen Atom
      • 8 - Adding Angular Momenta
      • 9 - Time-Independent Perturbation Theory
      • 10 - Identical Particles
  • Mathematisches Basiswissen für Theoretische Physik T2
  • QM-1-WaveFunction-Videos.nb
  • Exercises:
    • Informations for the exercises;
    • Problems:  sheet 1; sheet 2; sheet 3; sheet 4; sheet 5; sheet 6; sheet 7; sheet 8; sheet 9; sheet 10; sheet 11; sheet 12

• H. Neufeld: Particle physics II
  • Lecture notes:
    • Chapter 01: Introduction
    • Chapter 02: Scalar field
    • Chapter 03: Functional integral
    • Chapter 04: Perturbation theory
    • Chapter 05: Dimensional regularization and renormalization
    • Chapter 06: Renormalizability
    • Chapter 07: Reduction formalism
    • Chapter 08: Cross section
    • Chapter 09: Dirac field
    • Chapter 10: Fermionic path integral
    • Chapter 11: Abelian gauge field
    • Chapter 12: Interaction picture
    • Chapter 13: Quantum electrodynamics of spin 1/2 fermions
    • Chapter 14: Anomalous magnetic moments of electron and muon
    • Chapter 15: Nonabelian gauge theories
    • Chapter 16: Quantization of nonabelian gauge fields
    • Chapter 17: Spontaneous symmetry breaking
    • Chapter 18: Spontaneous breaking of local gauge symmetries
    • Chapter 19: Standard model of particle physics
    • Chapter 20: Decay width
    • Chapter 21: Massive vector field
  • Exercises: Problems 1-50;

SS 2015:

• H. Neufeld: Quantenmechanik II
  
  • Lecture announcement
  • Information about the exam
  • Lecture - manuscript:
    • 0. Path-Integral Quantization
    • 1. Quantum theory in the presence of an external electromagnetic field
    • 2. Quantization of the free electromagnetic field
    • 3. Systems of identical particles and quantum field theory
    • 4. Relativistic Quantum Field Theory
    • 5. Spin ½ Fields (Spinor fields)
    • 6. Quantization of the free Dirac field
    • 7. Basics of Quantum Elektrodynamics
    • 8. Interaction Picture and Perturbation Series
  • Exercises:
    • Information sheet
    • Problems 1-50;

WS 2014:

• H. Hüffel: Theoretische Physik I - Klassische Mechanik
  • Exercises: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 | sheet 10.

SS 2014:

• H. Neufeld: Quantenmechanik II
  • Lecture announcement
  • Lecture - manuscript:
    • 1. Die elektromagnetische Wechselwirkung in der Quantentheorie
    • 2. Die Quantisierung des freien elektromagnetischen Feldes
    • 3. Systeme identischer Teilchen und zweite Quantisierung
    • 4. Pfadintegral
      In this chapter, I follow largely the lecture notes of Matthias Blau (Bern), "Notes on (Semi-)Advanced Quantum Mechanics: The Path Integral Approach to Quantum Mechanics", available here
    • 5. Streutheorie
    • 6. Symmetries in Quantum Theory
    • 7. SU(2) und SO(3)
  • Exercises:
    
    • Information sheet
    • Problems 1-76
      
      

WS 2013:

• R. Bertlmann: Nonlocality, Entaglement and Geometry of Quantum Systems
  • Exercises: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9

• H. Hüffel: Statistische Physik II
  
  • Exercises: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 | sheet 10

• H. Neufeld: Theoretical Physics 3 (Electrodynamics)
  
  • Lecture Notes
  • Homework problems
  • Information for the exam

• H. Neufeld & Mathias Butenschön: Laboratory Theoretical Physics
  
  • Information sheet

SS 2013:

• R. Bertlmann: Decoherence and Physics of open Quantum Systems
  
  • Exercises: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9

• H. Hüffel: Mathematische Methoden der Physik I
  
  • Lecture notes
  • Exercises:
    
    • Exercise modalities
    • sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 | sheet 10 | sheet 11 | sheet 12
    • Solutions of test 1

• H. Rumpf: Theoretische Physik 4 - Thermodynamik und Statistische Physik I
  • Lecture notes:
    • Chapter 0: Einführung
    • Chapter 1: Grundbegriffe der klassischen und Quantenstatistik
    • Chapter 2: Statistische Beschreibung von Vielteilchensystemen
    • Chapter 3: Der klassische Grenzfall
    • Chapter 4: Einige Quantensysteme
    • Chapter 5: Allgemeine Thermodynamik
    • Chapter 6: Nichtgleichgewichtsprozesse
    • Chapter 7: Systeme mit Wechselwirkung
  • Exercises:
    • Problems 1-7 | 8-13 | 14-20 | 21-27 | 28-34 | 35-42 | 43-49 | 50-56 | 57-63

WS 2012:

• M. Könenberg: Mathematische Methoden der Physik II
  • Exercises: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9 | sheet 10 | sheet 11 | sheet 12

SS 2012:

• H. Hüffel: Mathematische Methoden der Physik I
  
  • Lecture notes
  • Exercises:
    • Problems 1-5 |6-10 | 11-15 | 16-20 | 21-25 | 26-30 | 31-35 | 36-45 | 46-47 | 48-52 | 53-57

• H. Neufeld: Theoretische Physik 2 - Quantenmechanik I
  • Lecture:
    • Lecture notes
    • Mathematisches Basiswissen für Theoretische Physik T2
  • Exercises:
    
    • Informations for the exercises;
    • Problems 1-10 | 11-13 | 14-22 | 23-30 | 31-40 | 41-46 | 47-55 | 56-65

WS 2011:

• R. Bertlmann: Theoretische Physik für das Lehramt L2
  • Lecture: Contents; detailed contents of Quantum Mechanics
    
    • further Documents for download (http://csteiner.12hp.de):
      • L2 lecture notes (Quantum Mechanics and Statistics) by Ch. Steiner
      • EPR Paradoxon (talk by Natalie Romanov)
      • Einstein's Relativitätstheorie (talks by Ph. Köhler)
  • Exercises:
    
    • Problems1-6 | 7-11 | 12-16 | 17-22 | 23-27 | 28-32 | 33-37 | 38-42 | 43-48
  • Discussion Examples:
    • Discussion Example 0 - Photoelektrischer Effekt
    • Discussion Example 1 - Schrödingers Katze
    • Discussion Example 2 - Heisenberg'sche Unschärferelation
    • Discussion Example 3 - Tunneleffekt mit Anwendung
    • Discussion Example 4 - Quantenmechanik in der Schule 1
    • Discussion Example 5 - Quantenmechanik und Schule 2
    • Discussion Example 6 - Brownsche
 Molekularbewegung
    • Discussion Example 7 - Doppelspalt
    • Das Münchener Unterrichtskonzept zur Quantenmechanik von R. Müller und H Wiesner

SS 2011:

• H. Hüffel: Theoretische Physik IV: Thermodynamik und statistische Physik I
  • Exam questions
  • Exercises:
    
    • sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9
      

• H. Rumpf: Theoretische Physik II: Quantenmechanik I
  
  • Lecture notes
  • Exercises:
    
    • sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 (Solutions of sheet 5)| sheet 6

WS 2010:

• R. Bertlmann: Nonlocality, Entanglement, and Geometry of Quantum Systems
  • Exercises: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9

SS 2010:

• R. Bertlmann: Theoretische Physik 2 - Quantenmechanik I - Übungen
  • Problem sheets: sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7 | sheet 8 | sheet 9
    
    

• H. Neufeld: Particle Physics II
• Lecture notes:
  • 01: Scalar field
  • 02: Functional integral
  • 03: Dirac field
  • 04: Fermionic path integral
  • 05: Massive vector field
  • 06: Abelian gauge field
  • 07: Perturbation theory
  • 08: Quantum electrodynamics (QED) of spin ½ fermions
  • 09: Production of fermion pairs in electron-positron collisions
  • 10: Feynman graphs
  • 11: Cross section
  • 12: Nonabelian gauge theories
  • 13: Spontaneous symmetry breaking
  • 14: Spontaneous breaking of local gauge symmetries
  • 15: Standard model of particle physics
  • 16: Two-point function of an interacting theory
  • 17: Reduction formalism
  • 18: QED two-point function for fermions
  • 19: Photon two-point function at one-loop
  • 20: Vertex correction in QED
  • 21: Renormalized perturbation theory
  • 22: Electron scattering by an external field
  • 23: Cross-section formula for the scattering by a time-independent potential
  • 24: Cancellation of IR-divergences
• Exercises:
  Problems 1-11 | 12-19 | 20-27 | 28-41 | 42-49

• H. Verschelde & V. Zakharov: Relativistic Quantum Field Theory
  • Lecture notes:
    • chapter 01: Free quantum fields
    • chapter 02: Propagators, scattering theory and n-point functions

WS 2009:

• H. Hüffel: Theoretische Physik 1 - Klassische Mechanik
  • Lecture: Exam questions
  • Exercises: 1-10 | 11-15 | 16-20 | 21-25 | 26-30 | 31-35 | 36-40 | 41-45

• H. Rumpf: Theoretische Physik 3 - Elektrodynamik
  • Exercises: 1-8 | 9-15 | 16-19 | 20-24 | 25-29 | 30-38 | 39-48

SS 2009:

• R. A. Bertlmann: Decoherence and the physics of open quantum systems
  
  • Lecture script
    

• J-B. Bru: Quantenmechanik II - Exercises
  • Problems 1-6 | 7-11 | 12-16 | 17-21 | 22-26 | 27-31 | 32-38
    

• G. Ecker: Kern- und Teilchenphysik (für das Lehramt)
  • Lecture script

• H. Hüffel: Theoretische Methoden der Physik 4
  • Lecture script
    

• H. Neufeld: Particle Physics II
  • Lecture notes:
    • 01: Quantization of the electromagnetic field
    • 02: Scalar fields
    • 03: Functional integral
    • 04: Perturbation theory
    • 05: Dimensional regularization and renormalization
    • 06: Renormalizability
    • 07: Reduction formalism
    • 08: Cross section
    • 09: Dirac field
    • 10: Fermionic path integral
    • 11: Abelian gauge field
    • 12: Interaction picture and vacuum-to-vacuum transition amplitude
    • 13: Quantum electrodynamics of spin ½ fermions
    • 14: Anomalous magnetic moment of the electron
    • 15: Nonabelian gauge theories
    • 16: Quantization of nonabelian gauge fields
    • 17: Spontaneous symmetry breaking
    • 18: Spontaneous breaking of local gauge symmetries
    • 19: Standard model of particle physics
  • Exercises: Problems 1-11 | 12-22 | 23-25 | 26-31 | 32-40 | 41-53

• F. Verstraete: Theoretische Physik II - Quantenmechanik I
  
  • Exercises: 1-6 | 7-11 | 12-17 | 18-24 | 25-29 | 30-33

WS 2008:

• J. B. Bru: Mathematische Methoden der Physik II
  • exercises:
    
    • informations
    • exercises1-7 | 8-14 | 15-21 | 22-26

• G. Ecker: Theoretische Physik III: Elektrodynamik
  • Lecture script

• H. Neufeld: Theoretische Physik für das Lehramt L2
  
  • script (part II, Statistische Physik und Thermodynamik)

SS 2008:

• R. A. Bertlmann: Theoretische Physik T2
  • Lecture script
  • exercises
    • solutions for exercises 33 and 34

• H. Neufeld: Mathematische Methoden der Physik I
  
  • Lecture notes (final version: 10/2/2012)
  • exercises:
    • Information sheet for the exercises
    • sheet 1 | sheet 2 | sheet 3 | sheet 4 | sheet 5 | sheet 6

WS 2007:

• R. A. Bertlmann: Decoherence and the physics of open quantum systems
  
  • Lecture script

• G. Ecker: Theoretische Physik T1 - Klassische Mechanik
  • Lecture script

• S. Dittmaier: Electroweak Physics at the LHC
  • Introductory Lecture
  • SM and precision physics

SS 2007:

• P.C. Aichelburg: Übungen zu Theoretische Physik T2
  
  • sheet 3 | sheet 4 | sheet 5 | sheet 6 | sheet 7

• W. Grimus: Theoretische Physik T4: Statistische Physik und Thermodynamik
  • Exercises 1-62

SS 2006:

• R. Beig: Theoretische Methoden der Physik 2
  
  • exercises 1-33