General information
| Course name | Lecture: Fundamentals of plasma material interactions |
| Semester | WS 2021/22 |
| Current number of participants | 1 |
| expected number of participants | 38 |
| Home institute | Lehrstuhl für Experimentelle Plasmaphysik |
| Courses type | Lecture in category Teaching |
| First date | Thu., 21.10.2021 14:15 - 15:45, Room: (T-2004) |
| Participants |
Due to the current guidelines on room capacity and contact tracking, the following rules apply: - Registration via DigiCampus is mandatory to participate, access to the course without registration is excluded. - the registration is binding. It can be annulled by lecturers/tutors, but only in justified cases after the first event has started. - the number of participants is limited by the maximum capacity of the room (incl. teaching staff). |
| Pre-requisites | recommended: module 'Plasmaphysik und Fusionsforschung' |
| Performance record | Oral examination for entire module (30 min, 6 CP), i.e. on both lectures 'Fundamentals of plasma material interactions' (winter term) and 'High heat load components in nuclear fusion devices' (summer term) |
| Online/Digitale Veranstaltung | Veranstaltung wird in Präsenz abgehalten. |
| Hauptunterrichtssprache | englisch |
| Literaturhinweise |
P. Stangeby: The plasma boundary of magnetic fusion devices (IOP, 2000) R. Clark, D. Reiter (Eds.): Nuclear Fusion Research, Understanding Plasma-Surface Interactions (Springer, 2005) O. Auciello, D. L. Flamm (Eds.): Plasma Diagnostics, Volume 2: Surface Analysis and Interactions (Plasma-Materials Interactions) (Academic Press, 1989) M. Turnyanskiy et al.: European roadmap to the realization of fusion energy: Mission for solution on heat-exhaust systems (Fusion Engineering and Design, 2015) |
| Miscellanea |
General remarks: - This module is suitable as an extension to the module 'Plasmaphysik und Fusionsforschung'. - The two lectures of this module can be followed in an arbitrary order. Thus, the module can be started at a summer or winter term. Lecture contents: Fundamental plasma boundary physics Erosion processes: physical sputtering, chemical erosion, radiation induced sublimation, arcs Experimental observation of surface processes in plasmas Methods for characterizing surfaces Coating techniques Hydrogen retention Surface modification by plasmas |
| ECTS points | 6 (for entire module) |
