13D061KT - Quantum Transport
| Course specification | ||||
|---|---|---|---|---|
| Course title | Quantum Transport | |||
| Acronym | 13D061KT | |||
| Study programme | Electrical Engineering and Computing | |||
| Module | Nanoelectronics and Photonics | |||
| Type of study | doctoral studies | |||
| Lecturer (for classes) | ||||
| Lecturer/Associate (for practice) | ||||
| Lecturer/Associate (for OTC) | ||||
| ESPB | 9.0 | Status | elective | |
| Condition | no | |||
| The goal | Introducing students to phenomena of quantum transport in two-dimensional materials and nanoscale systems; grasping theoretical models of quantum transport and their applications to realistic nanoelectronic devices. | |||
| The outcome | It is expected that the students would: (1) apprehend quantum transport phenomena, (2) master theoretical models of quantum transport, and (3) be able to do independent research in modeling of nanoscale electron devices, especially those based on twodimensional materials. | |||
| Contents | ||||
| Contents of lectures | Balistic transport. Landauer-Büttiker formalism. Tunneling phenomena: resonant tunneling, Fano resonances. Coulomb blockade: tunneling Hamiltonian, sequential tunneling. The nonequilibrium Green function method. Topological phenomena in quantum transport. Fluctuations and correlations. Spin quantum transport. Electronic devices based on 2D materials and their structures. | |||
| Contents of exercises | ||||
| Literature | ||||
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| Number of hours per week during the semester/trimester/year | ||||
| Lectures | Exercises | OTC | Study and Research | Other classes |
| 6 | ||||
| Methods of teaching | lectures | |||
| Knowledge score (maximum points 100) | ||||
| Pre obligations | Points | Final exam | Points | |
| Activites during lectures | Test paper | 70 | ||
| Practical lessons | Oral examination | |||
| Projects | ||||
| Colloquia | ||||
| Seminars | 30 | |||