Plasma filaments in magnetically confined plasmas

Nyomtatóbarát változatNyomtatóbarát változat
PhD típus: 
Fizikai Tudományok Doktori Iskola
Sandor Zoletnik
Email cím:
Centre for Energy Research
Head of department
Tudományos fokozat: 
Pokol Gergő
Email cím:
Tudományos fokozat: 

Magnetic fusion research aims at energy production on Earth using nuclear fusion reactions. This method would be a greenhouse gas free, sustainable source of baseload electricity without generating long-lived nuclear waste. The problem is that a fusion reactor needs to confine 100 million C temperature Hydrogen plasma which is only possible by strong magnetic fields. The two basic categories of magnetic confinement fusion devices are tokamaks and stellarators. The former has simple axisymmetric geometry while the latter has complicated 3D form. Plasma confinement is studied in both device types on large, industrial-scale experiments. The Centre for Energy Research is participating in most large international experiments by designing, building and operating specialised plasma diagnostic devices and by comparing experimental findings with theory.

In both devices the edge plasma is prone to instabilities which cause random ejection of plasma filaments. These filaments deteriorate the device performance and threaten the solid state environment. The physics of filaments has been studied in the 2D geometry on tokamaks, but on the Wendelstein 7-X stellarator they were only found recently by Hungarian researchers. In this complicated 3D device filaments appear to enter the edge “island divertor” and move energy and particles from the edge plasma to the island core. Also the filament activity is dependent on plasma conditions, in some parameter regimes quasi-coherent oscillations and low frequency modulations are also observed in edge parameters.

The aim of the Ph.D. research topic is the analysis of experimental data obtained from specialised diagnostic to reveal the 3D structure and motion of filaments, their interaction with the edge plasma parameters. Also comparison with our own measurements on tokamak devices and with modeling by other groups are planned. The Wendelstein 7-X experiment is ondergoing upgrade until 2021. After the restart new experiments are planned with upgraded diagnostics where the analysis techniques and findings of the student would play an important role. The student is also expected to take part in these experiments.




English language reading/writing/communication, basic knoweldge in numerical analysis methods and programming (Python), willingness to work several months or longer time abroad in international team 

Munkahely neve: 
Centre for Energy Research / Energiatudományi Kutatóközpont
Munkahely címe: 
1121 Budapest, Konkoly Thege u 29-33