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Main Authors: Bonitz, M., Kählert, H., Krimans, D., Makait, C., Hamann, P., Vorberger, J., Moldabekov, Zh., Hu, S. X., Karasiev, V. V., Kraus, D., Kersten, H., Joost, J. -P., Ludwig, P., Dornheim, T.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.03757
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author Bonitz, M.
Kählert, H.
Krimans, D.
Makait, C.
Hamann, P.
Vorberger, J.
Moldabekov, Zh.
Hu, S. X.
Karasiev, V. V.
Kraus, D.
Kersten, H.
Joost, J. -P.
Ludwig, P.
Dornheim, T.
author_facet Bonitz, M.
Kählert, H.
Krimans, D.
Makait, C.
Hamann, P.
Vorberger, J.
Moldabekov, Zh.
Hu, S. X.
Karasiev, V. V.
Kraus, D.
Kersten, H.
Joost, J. -P.
Ludwig, P.
Dornheim, T.
contents The year 2025 had been designated by UNESCO as the International Year of Quantum Science and Technology. 125 years ago Max Planck's discovery of radiation quanta started the quantum era and 100 years ago quantum mechanics was discovered by Schroedinger, Heisenberg, Bohr, Pauli, Dirac, Born, Fermi and many others. By now, quantum mechanics is the theoretical foundation of most fields of physics and chemistry, and it is the basis for modern nanotechnology. How about plasma physics? How important are quantum effects in plasmas? In what experiments quantum effects are observed and where do they govern the behavior of plasmas? How can these effects be treated theoretically and via computer simulations? Starting with a brief historical overview we discuss the broad parameter range that is characteristic for plasmas and outline where quantum effects are relevant. This is the case primarily for warm dense matter and inertial fusion plasmas. We provide an overview on the theoretical quantum methods that are available for these dense plasmas and how their respective advantages can be combined in order to achieve predictive capability. The key is a downfolding approach that is based on first principles simulations.
format Preprint
id arxiv_https___arxiv_org_abs_2604_03757
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantum effects in plasmas
Bonitz, M.
Kählert, H.
Krimans, D.
Makait, C.
Hamann, P.
Vorberger, J.
Moldabekov, Zh.
Hu, S. X.
Karasiev, V. V.
Kraus, D.
Kersten, H.
Joost, J. -P.
Ludwig, P.
Dornheim, T.
Plasma Physics
Quantum Physics
The year 2025 had been designated by UNESCO as the International Year of Quantum Science and Technology. 125 years ago Max Planck's discovery of radiation quanta started the quantum era and 100 years ago quantum mechanics was discovered by Schroedinger, Heisenberg, Bohr, Pauli, Dirac, Born, Fermi and many others. By now, quantum mechanics is the theoretical foundation of most fields of physics and chemistry, and it is the basis for modern nanotechnology. How about plasma physics? How important are quantum effects in plasmas? In what experiments quantum effects are observed and where do they govern the behavior of plasmas? How can these effects be treated theoretically and via computer simulations? Starting with a brief historical overview we discuss the broad parameter range that is characteristic for plasmas and outline where quantum effects are relevant. This is the case primarily for warm dense matter and inertial fusion plasmas. We provide an overview on the theoretical quantum methods that are available for these dense plasmas and how their respective advantages can be combined in order to achieve predictive capability. The key is a downfolding approach that is based on first principles simulations.
title Quantum effects in plasmas
topic Plasma Physics
Quantum Physics
url https://arxiv.org/abs/2604.03757