Fusion and Plasma Physics

The Fusion and Plasma Physics group at Aalto University investigates experimentally and by computer simulations plasma phenomena in magnetically confined fusion plasma physics. The overall goal is to create a new, clean and virtually unlimited energy source.

Flux surface diagnostics: field line visualization in Wendelstein 7-X stellarator. Photo: Matthias Otte / IPP

The fusion process encompasses light elements, such as hydrogen and its isotopes deuterium and tritium, to merge to heavier elements, such as helium, thereby releasing large amounts of energy in form of MeV neutrons and protons. To harness this energy, a plasma needs to confined either magnetically or inertially, and heated to temperatures in excess of 100 million Kelvins. At these temperatures the fusion process becomes self-sustained by heating of the plasma via energetic by-products, such as helium. The fusion challenge consists in confining the plasma sufficiently long and controlling its interaction with the surrounding walls.

The group’s research activities concentrate on the tokamak concept. We participate in experiments at present fusion facilities, such as ASDEX Upgrade, DIII-D, and JET, develop and validate computational models for present and future, burning-plasma reactors, such as ITER, and develop diagnostics for fusion relevant experiments.

The group is part of FinnFusion, the domestic agency administrating fusion research within EUROfusion, and member of FuseNet, the European Fusion Education Network facilitating student exchange at Bachelor's, Master's and PhD level. The group is supported by the Academy of Finland and other funding agencies.

Group leader

Mathias Groth

Research

The main research interests are listed below, including codes, experimental apparatuses and facilities, and major scientific results.

Codes used and developed by the Fusion and Plasma Physics group

Particle orbit simulations: ASCOT → contact: Antti Snicker (antti.snicker@vtt.fi)
Plasma turbulence: ELMFIRE (mothballed)
Scrape-off layer and plasma-wall interaction

Experimental plasma-wall interaction research

Collaboration with experimental research institutes

Open positions

Currently, there are no vacant positions. However, open application to Prof. Mathias Groth (mathias.groth@aalto.fi) are encouraged and reviewed on case-by-case basis.

Latest publications

GENE simulations of GAM-turbulence interactions in FT-2 tokamak

F. Albert, T. P. Kiviniemi, L. Chôné, S. Janhunen, S. Leerink, E. Hirvijoki, R. N. Iorio 2025 Plasma Physics and Controlled Fusion

Demonstration of Super-X divertor exhaust control for transient heat load management in compact fusion reactors

Francis Albert Devasagayam, Ray Chandra, Nima Fakhrayi Mofrad, Mathias Groth, Timo Kiviniemi, Henri Kumpulainen, Susan Leerink, Roni Mäenpää, Patrik Ollus, David Rees, Lucia Sanchis, Andrea Sand, Seppo Sipilä, Vladimir Solokha, Jari Varje 2025 arXiv.org

Demonstrating the impact of ro-vibrationally excited H₂ on divertor detachment via population modelling

Richard C. Bergmayr, Dirk Wünderlich, Mathias Groth, Liam H. Scarlett, Dmitry V. Fursa, Mark C. Zammit, Igor Bray, Ursel Fantz 2025 Nuclear Materials and Energy

Validation of SOLPS-ITER and EDGE2D-EIRENE simulations for H, D, and T JET ITER-like wall low-confinement mode plasmas

N. Horsten, M. Groth, V. P. Rikala, B. Lomanowski, A. G. Meigs, S. Aleiferis, X. Bonnin, G. Corrigan, W. Dekeyser, R. Futtersack, D. Harting, D. Reiter, V. Solokha, B. Thomas, S. Van den Kerkhof, N. Vervloesem 2025 Nuclear Materials and Energy

Addressing the impact of Lyman opacity in inference of divertor plasma conditions with 2D spectroscopic camera analysis of Balmer emission during detachment in JET L-mode plasmas

J. Karhunen, B. Lomanowski, S. Aleiferis, P. Carvalho, M. Groth, A. Holm, K. D. Lawson, A. G. Meigs, A. Shaw, V. Solokha 2025 Nuclear Materials and Energy

The role of SOL plasma in the confinement of NBI fast ions in W7-X

T. P. Kiviniemi, T. Kurki-Suonio, S. Lazerson, S. Äkäslompolo, P. Ollus, L. Sanchis, D. Kulla 2025 Plasma Physics and Controlled Fusion

Impact of bivariate energy and angular atomic impact spectra on tungsten erosion in JET

H. A. Kumpulainen, D. Reiter, S. Brezinsek, M. Groth, J. Romazanov, S. Wiesen 2025 Plasma Physics and Controlled Fusion

Balmer emission measurements in JET-ILW hydrogen, deuterium, tritium and deuterium-tritium low-confinement mode plasmas

A. G. Meigs, M. Groth, V. P. Rikala, B. Lomanowski, N. Vianello, M. Wischmeier 2025 Nuclear Materials and Energy

Divertor shaping with neutral baffling as a solution to the tokamak power exhaust challenge

D. Moulton, A. Hakola, H. Yang, J. Varje, H. J. Sun, V. Solokha, A. Snicker, S. Smith, S. Sipilä, J. Simpson, C. Silva, R. Sharma, P. Schneider, K. Särkimäki, J. Santos, A. Sand, L. Sanchis, A. Salmi, P. Ryan, R. Rossi, D. Rees, P. Ollus, S. K. Nielsen, D. Moulton, M. Marin, Y. Liang, S. Leerink, H. Kumpulainen, U. Kumar, T. Kiviniemi, A. Kirjasuo, D. King, H. T. Kim, J. Karhunen, A. Järvinen, Z. Huang, J. Huang, N. Horsten, A. Hakola, M. Groth, X. Feng, N. Fakhrayi Mofrad, J. Eriksson, H. Chen, R. Chandra, J. Cai, F. C.P. Albert Devasagayam, E. Rose, R. Martin, B. A. Lomanowski, Y. Q. Liu, D. King, Z. P. Chen, S. Ahmed 2025 arXiv.org

Impact of nitrogen molecular breakup on divertor conditions in JET L-mode plasmas using SOLPS-ITER

R. Mäenpää, H. Kumpulainen, M. Groth, N. Horsten, D. Reiter, J. Romazanov, B. Lomanowski, S. Brezinsek, J. Karhunen, K. D. Lawson, A. G. Meigs, S. Menmuir, A. Shaw 2025 Nuclear Materials and Energy

More information on our research in the Aalto research portal.

Research portal