Quantum MechanicsII
Keywords |
Classification |
Keyword |
OFICIAL |
Physics |
Instance: 2024/2025 - 2S
Cycles of Study/Courses
Acronym |
No. of Students |
Study Plan |
Curricular Years |
Credits UCN |
Credits ECTS |
Contact hours |
Total Time |
L:F |
24 |
Official Study Plan |
3 |
- |
6 |
48 |
162 |
Teaching Staff - Responsibilities
Teaching language
Suitable for English-speaking students
Objectives
Improving the student’s training in Quantum Mechanics by learning methods of approximate resolution of the Schrodinger equation, study of the scattering theory, symmetries and conservation laws, identical particle systems and 2nd quantification. To acquire knowledge and skills to facilitate the assimilation of results from literature in disciplines where Quantum Physics is essential: Particle Physics, Condensed Matter Physics, Quantum Optics, Astrophysics, etc.Learning outcomes and competences
After completing this course the student should have a working knowledge of quantum concepts enabling him/her to read and comprehend literature in fields with a strong component on Quantum Physics such as Particle Physics, Condensed Matter Physics, Quantum Optics, Astrophysics, etc.
Working method
Presencial
Pre-requirements (prior knowledge) and co-requirements (common knowledge)
Modern Physics, Quantum Mechanics I
Program
1. Review of QM:
State space. Dirac notation. Operators and observables. Commutation relations. Complete set of compatible observables. Unitary transformations. Evolution operator, Schroedinger and Heisenberg representations.
2. Approximate methods in QM:
Time independent perturbation theory (review). Variational methods. Time dependent perturbation thoery. Fermi's golden rule. Adiabatic approximation.
3. Scattering theory:
Revision of the classical case. Scattering cross section and scattering amplitude. Born approximation: Born series; diagrammatic interpretation; first Born approximation. Partial waves and phase shifts.
4. Symmetries and conservation laws:
Unitary transformations. Symmetry transformations and generators. Conservation laws. Discrete symmetries.
5. Identical particles:
N-particles systems. Product space and non-distinguishability. Occupation numbers. Bosons and fermions. Fock space. Second quantification. Symmetric and anti-symmetric wavefunctions: Slater determinants.
Mandatory literature
Griffiths David J.;
Introduction to quantum mechanics. ISBN: 0-13-191175-9
Cohen-Tannoudji, Claude; Diu, Bernard; Laloe, Frank; Quantum mechanics. ISBN: ISBN 0-471-16435-X Vol. 2
Baym Gordon;
Lectures on quantum mechanics. ISBN: 0-8053-0667-6
Sakurai J. J. 1933-1982;
Modern quantum mechanics. ISBN: 0-201-53929-2
Complementary Bibliography
Pedro José de Almeida Bicudo;
Mecânica quântica. ISBN: 978-989-8481-54-2
Teaching methods and learning activities
In theoretical lectures the topics are presented; in the classes of problems these are discussed and solved, after being made available in advance for autonomous work.
Evaluation Type
Evaluation with final exam
Assessment Components
designation |
Weight (%) |
Exame |
100,00 |
Total: |
100,00 |
Amount of time allocated to each course unit
designation |
Time (hours) |
Estudo autónomo |
114,00 |
Frequência das aulas |
48,00 |
Total: |
162,00 |
Eligibility for exams
Only final exam.
Calculation formula of final grade
final exam 100%
Classification improvement
According to FCUP rules.
Observations
Jury of the curricular unit
:
M . Fátima Mota
José Miguel Nunes da Silva
Miguel Costa