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Main Authors: Frank, S. J., Viola, J., Petrov, Yu. V., Anderson, J. K., Bindl, D., Biswas, B., Caneses, J., Endrizzi, D., Furlong, K., Harvey, R. W., Jacobson, C. M., Lindley, B., Marriott, E., Schmitz, O., Shih, K., Sutherland, D. A., Forest, C. B.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.06644
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author Frank, S. J.
Viola, J.
Petrov, Yu. V.
Anderson, J. K.
Bindl, D.
Biswas, B.
Caneses, J.
Endrizzi, D.
Furlong, K.
Harvey, R. W.
Jacobson, C. M.
Lindley, B.
Marriott, E.
Schmitz, O.
Shih, K.
Sutherland, D. A.
Forest, C. B.
author_facet Frank, S. J.
Viola, J.
Petrov, Yu. V.
Anderson, J. K.
Bindl, D.
Biswas, B.
Caneses, J.
Endrizzi, D.
Furlong, K.
Harvey, R. W.
Jacobson, C. M.
Lindley, B.
Marriott, E.
Schmitz, O.
Shih, K.
Sutherland, D. A.
Forest, C. B.
contents This paper presents Hammir tandem mirror confinement performance analysis based on Realta Fusion's first-of-a-kind model for axisymmetric magnetic mirror fusion performance. This model uses an integrated end plug simulation model including, heating, equilibrium, and transport combined with a new formulation of the plasma operation contours (POPCONs) technique for the tandem mirror central cell. Using this model in concert with machine learning optimization techniques, it is shown that an end plug utilizing high temperature superconducting magnets and modern neutral beams enables a classical tandem mirror pilot plant producing a fusion gain Q > 5. The approach here represents an important advance in tandem mirror design. The high fidelity end plug model enables calculations of heating and transport in the highly non-Maxwellian end plug to be made more accurately. The detailed end plug modelling performed in this work has highlighted the importance of classical radial transport and neutral beam absorption efficiency on end plug viability. The central cell POPCON technique allows consideration of a wide range of parameters in the relatively simple near-Maxwellian central cell, facilitating the selection of more optimal central cell plasmas. These advances make it possible to find more conservative classical tandem mirror fusion pilot plant operating points with lower temperatures, neutral beam energies, and end plug performance requirements than designs in the literature. Despite being more conservative, it is shown that these operating points have sufficient confinement performance to serve as the basis of a viable fusion pilot plant provided that they can be stabilized against MHD and trapped particle modes.
format Preprint
id arxiv_https___arxiv_org_abs_2411_06644
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Confinement performance predictions for a high field axisymmetric tandem mirror
Frank, S. J.
Viola, J.
Petrov, Yu. V.
Anderson, J. K.
Bindl, D.
Biswas, B.
Caneses, J.
Endrizzi, D.
Furlong, K.
Harvey, R. W.
Jacobson, C. M.
Lindley, B.
Marriott, E.
Schmitz, O.
Shih, K.
Sutherland, D. A.
Forest, C. B.
Plasma Physics
This paper presents Hammir tandem mirror confinement performance analysis based on Realta Fusion's first-of-a-kind model for axisymmetric magnetic mirror fusion performance. This model uses an integrated end plug simulation model including, heating, equilibrium, and transport combined with a new formulation of the plasma operation contours (POPCONs) technique for the tandem mirror central cell. Using this model in concert with machine learning optimization techniques, it is shown that an end plug utilizing high temperature superconducting magnets and modern neutral beams enables a classical tandem mirror pilot plant producing a fusion gain Q > 5. The approach here represents an important advance in tandem mirror design. The high fidelity end plug model enables calculations of heating and transport in the highly non-Maxwellian end plug to be made more accurately. The detailed end plug modelling performed in this work has highlighted the importance of classical radial transport and neutral beam absorption efficiency on end plug viability. The central cell POPCON technique allows consideration of a wide range of parameters in the relatively simple near-Maxwellian central cell, facilitating the selection of more optimal central cell plasmas. These advances make it possible to find more conservative classical tandem mirror fusion pilot plant operating points with lower temperatures, neutral beam energies, and end plug performance requirements than designs in the literature. Despite being more conservative, it is shown that these operating points have sufficient confinement performance to serve as the basis of a viable fusion pilot plant provided that they can be stabilized against MHD and trapped particle modes.
title Confinement performance predictions for a high field axisymmetric tandem mirror
topic Plasma Physics
url https://arxiv.org/abs/2411.06644