 | | |
| ELEN0069-1 | Nanoelectronics / Optoelectronics
|
|
| Duration : | 30h Th, 30h Pr |
|
| Number of credits : |
| Master in Biomedical Engineering, research focus, 2nd year | | 5 |
|
| Master in Biomedical Engineering, research focus, 2nd year | | 5 |
|
| Master in Electrical Engineering, research focus, 2nd year | | 5 |
|
| Master in Electrical Engineering, research focus, 2nd year | | 5 |
|
| Master in Engineering Physics, research focus, 2nd year | | 5 |
|
| Advanced Master in Nanotechnology | | 5 |
|
|
|
| Lecturer : | Benoît Vanderheyden |
|
Language(s) of instruction :
|
| French language |
|
Organisation and examination :
|
| Teaching in the second semester |
|
Course contents :
|
| This course is a follow-up of the course "ELEN004-1 - Physical electronics". It hinges on two parts:
-
optoelectronic part: fundamental mechanisms for the emission or the absorption of an electromagnetic radiation by a semiconductor; exploitation of these mechanisms in optoelectronical devices;
-
nanoelectronic part: presentation of the technical and physical limitations faced by the integrated electronics industry; main elements of wave mechanics; discussion of the physical mechanisms that will potentially be used in future applications of integrated electronics.
More specifically, the following elements are seen:
heterostructures, electrical and optical properties of low-dimensionality devices (MODFET, quantum wells, wires, and dots), tunnel effect, mesoscopic effects and devices of nanometric sizes. |
|
Learning outcomes of the course :
|
| To be able to:
- explain how basic optoelectronic devices work;
- understand the relationships between the orders of magnitude of the involved physical mechanisms and the design constraints of such devices;
- explain the main technical and physical limitations of integrated electronic devices;
- explain, by means of examples seen in the lectures, the interest of heterostructures and of low-dimensionality devices;
- explain certain quantum mechanisms for transporting charge carriers (such as the tunnel effect) and appreciate their potentials for designing electronic devices.
The completion of a project enables the student to consult the scientific and technical litterature in english, make a bibliographic search, and expose clearly and briefly complex physical concepts. |
|
Prerequisites and co-requisites/ Recommended optional programme components :
|
| An introductory course on the physics of semiconductor devices (to the level of the first eight chapters of Streetman) |
|
Planned learning activities and teaching methods :
|
| Depending on the number of registered students, individual or group project, to be presented orally. |
|
Mode of delivery (face-to-face ; distance-learning) :
|
| Face-to-face |
|
Recommended or required readings :
|
|
slides (available from the lecturer).Textbooks :
Davies, The Physics of Low-dimensional Semiconductors (Cambridge U Press).
Matthieu, Physique des semiconducteurs et des composants électroniques (Dunod) |
|
Assessment methods and criteria :
|
|
- Project (to be presented orally), 50%
|
|
Work placement(s) :
|
| |
|
Organizational remarks :
|
| For more information, consult
http://www.montefiore.ulg.ac.be/~vdh/elen069.html |
|
Contacts :
|
| Benoît Vanderheyden, B.Vanderheyden @ ulg.ac.be |
|
|
| Items online : |
|
| Notes (password provided in class) |
| Basic course material |
|
|
