Module Information
Course Delivery
| Delivery Type | Delivery length / details |
|---|---|
| Lecture | 20 |
| Workload Breakdown | 20 hrs lectures 20 hrs example sheet work 60 hrs private study |
Assessment
| Assessment Type | Assessment length / details | Proportion |
|---|---|---|
| Semester Exam | 2 Hours written examination | 60% |
| Semester Assessment | Example sheets | 40% |
| Supplementary Exam | 2 Hours written examination | 100% |
| Semester Assessment | Assignment | 40% |
| Semester Exam | 2 Hours Semester Examination | 60% |
Learning Outcomes
On successful completion of this module students should be able to:
1. Apply the concepts of quantum mechanics in molecules, atoms, nuclei and fundamental particles
2. Define a photon and give examples which illustrate its importance
3. State the de Broglie hypothesis and outline the experimental evidence for it.
4. Interpret the wavefunction and use it to demonstrate the key concepts of quantisation of particles in potential wells.
5. Analyse experimental data in terms of quantisation
6. Demonstrate quantum ideas in the understanding of molecular and condensed matter physics
7. Summarise the basic structure of nuclei
8. Explain the stability or otherwise of nuclei
9. Explain the classification of elementary particles into quarks and leptons
Aims
This module introduces the fundamental aspects of quantum physics in the undergraduate physics programme.
Brief description
Quantum mechanics is the most successful physics theory created by mankind. It explains aspects of physics ranging from neutron stars through to sub-nuclear particles such as quarks. The module will introduce the concepts of quantum mechanics and use these to explain phenomena in molecular, atomic, nuclear and subnuclear particle physics.
Content
Matter waves and the de Broglie relation. Verification by Davisson-Germer
The wavefunction and its interpretation.
Quantisation - examples in square well potential, simple harmonic oscillator potential and Coulombic potential. Line spectra and the Franck-Hertz experiment.
The Heisenberg Uncertainty Principle
The Schrodinger equation and the quantum numbers of hydrogen. Electron spin. The Pauli Exclusion Principle and multi-electron atoms.
Tunneling of particles through potential barriers.
Molecular orbitals and covalent bonding.
Ionic and van der Waals bonds. Inter-atomic energy curve.
Crystalline and amorphous solids. Types of crystals, crystal organisation.
Electrons in crystals: introduction to band theory. Conductors, insulators, semiconductors
The atomic nucleus. Structure of the nucleus and its experimental determination
Radioactivity
The Standard model of elementary particles.
Module Skills
| Skills Type | Skills details |
|---|---|
| Application of Number | Example sheets and exam have a strong algebraic and numerical contribution. |
| Improving own Learning and Performance | Students will have feedback through marked example sheets which will improve their learning |
| Information Technology | Students will use java applets from web to illustrate key ideas. |
| Problem solving | During example sheets which are a series of physics problems. |
Reading List
Essential ReadingFrench, A.P. (1979 (various) An introduction to quantum physics /A.P. French, Edwin F. Taylor. Nelson Primo search Supplementary Text
Phillips, A. C. (c2003.) Introduction to quantum mechanics /A.C. Phillips. Wiley Primo search
Notes
This module is at CQFW Level 4