DTU Studieprojekt - Development of magnetical confinement fusion device at DTU

Development of magnetical confinement fusion device at DTU

Udbyder
Vejleder
Sted
København og omegn
Fusion energy has the potential to become the clean unlimited energy source of the future. The success of fusion energy presently relies on the understanding and the optimization of plasma dynamics inside a magnetic confinement fusion device called a tokamak. The first tokamak at DTU has just entered plasma mode and a number of research projects are ready to be carried out. In the section of Plasma Physics and Fusion Energy we are looking for students to help in this exciting period of time. First plasma was achieved in late March 2019 (see picture) and we are currently looking for students to construct plasma diagnostics, characterize and optimize the plasma operation, and to assist in our general research program.

As a Research Immersion, BSc, or MSc project we have many different possibilities for student who want to work with our new tokamak. A project could include one of the following topics:

· Determine plasma breakdown (generation) conditions using microwaves

· Development of light emission diagnostics

· Detection of plasma waves generated in the plasma

· Development of probe diagnostic for temperature measurements (we expect temperatures of 3 million degrees C).

Numerical projects related to the tokamak are also possible.

Please contact Stefan Kragh Nielsen at skni@fysik.dtu.dk for further information.

Emneord

• Elektroteknologi
• Fysik
• Geovidenskab
• Materialer
• Rumforskning
• Elektromagnetisme
• Elektronik
• Lyd
• Mikrobølgeteknologi
• Robotteknik og automation
• Energisystemer
• Lasere
• Mikro- og nanoteknologi
• Optik
• Sensorer
• Geologi
• Isforskning
• Jordens magnetfelt
• Klimaændringer
• Kortlægning og opmåling
• Hardware og komponenter
• Telekommunikation
• Nanopartikler
• Høreapparater
• Medicinske apparater og systemer
• Astrofysik
• Jordobservation
• Kosmisk stråling
• Rumteknologi og instrumenter
• Satellitter
• Solsystemet

Navn
Stefan Kragh Nielsen

Stilling
Seniorforsker

Mail
skni@fysik.dtu.dk

Vejleder-info
Bachelor i Elektroteknologi
Vejleder
Stefan Kragh Nielsen

ECTS-point
5 - 30

Type
Afgangsprojekt, Andet, Bachelorprojekt, Fagprojekt, Kandidatspeciale, Kursusrelaterede projekter, Specialkursus

Bachelor i Fysik og Nanoteknologi
Vejleder
Stefan Kragh Nielsen

ECTS-point
5 - 30

Type
Afgangsprojekt, Andet, Bachelorprojekt, Fagprojekt, Kandidatspeciale, Kursusrelaterede projekter, Specialkursus

Bachelor i General Engineering
Vejleder
Stefan Kragh Nielsen

ECTS-point
5 - 30

Type
Afgangsprojekt, Andet, Bachelorprojekt, Fagprojekt, Kandidatspeciale, Kursusrelaterede projekter, Specialkursus

Bachelor i Geofysik og Rumteknologi
Vejleder
Stefan Kragh Nielsen

ECTS-point
5 - 30

Type
Afgangsprojekt, Andet, Bachelorprojekt, Fagprojekt, Kandidatspeciale, Kursusrelaterede projekter, Specialkursus

Kandidatuddannelsen i Fysik og Nanoteknologi
Vejleder
Stefan Kragh Nielsen

ECTS-point
5 - 30

Type
Afgangsprojekt, Andet, Bachelorprojekt, Fagprojekt, Kandidatspeciale, Kursusrelaterede projekter, Specialkursus

Kandidatuddannelsen i Geofysik og Rumteknologi
Vejleder
Stefan Kragh Nielsen

ECTS-point
5 - 30

Type
Afgangsprojekt, Andet, Bachelorprojekt, Fagprojekt, Kandidatspeciale, Kursusrelaterede projekter, Specialkursus