On a High-Mirror Stellarator Reactor Exploratory Concept with Neutrons Concentrated on Centrifuge Liquids

V. Queral, I. Fernández, A. De Castro, D. Spong, S. Cabrera, V. Tribaldos, J. M. Reynolds, E. Rincón

Research output: Contribution to journalArticlepeer-review

Abstract

In the framework of fusion energy research based on magnetic confinement, stellarators allow numerous degrees of freedom for the design of the magnetic trap and plasma shape. Taking advantage of these features, some plasma shapes might benefit several of the many integrated elements involved in commercial fusion reactors, like, e.g., decreasing the number, mass and complexity of replaced activated in-vessel components (IVC) (i.e., by using liquids), extraction of large power, tritium generation, and remote maintenance. Certainly, free-surface liquid materials were proposed for tokamaks and field-reversed configuration (FRC) to try to improve some of such elements, i.e., in advanced power extraction (APEX) studies. Some reactor-relevant quasi-isodynamic (QI) magnetic configurations exhibit a relatively straight sector of plasma and high magnetic mirror. The combination of those elements and possibilities in a single stellarator reactor concept might have some advantages, in spite of the uncertainties due to the current low technological readiness level (TRL). The proposed and studied reactor concept is based on a vacuum vessel having short curved sectors and longer wide cylindrical sectors, which encloses a high-mirror low-vertical-excursion magnetic configuration, and swirling liquids or rotating cylinders, which centrifuge molten Li salts located at the low field region. Thus, the molten salts (if possible covered by a thin layer of liquid lithium) would be located on the internal perimeter of the cylinder, to act as particle exhaust (except for helium), neutron power extractor, and tritium breeder. The high-mirror feature tries to concentrate the neutron power at the cylindrical sectors, which might avoid using breeding materials at the curved sectors. The different elements of the concept are exploratorily studied and defined, and the difficulties assessed.

Original languageEnglish
Pages (from-to)3731-3737
Number of pages7
JournalIEEE Transactions on Plasma Science
Volume52
Issue number9
DOIs
StatePublished - 2024

Funding

This work was supported in part by the Agencia Estatal de Investigaci\u00F3n (AEI), in part by the Ministry of Science and Innovation, and in part by the European Funds Fondo Europeo de Desarrollo Regional (FEDER) EU, under Grant PID2021-123616OB-I00, for the project \"Study of improved stellarator assemblies consistent with proper in-vessel components for viable high-field stellarator reactors\".

FundersFunder number
Agencia Estatal de Investigación
Ministerio de Ciencia e Innovación
European Regional Development FundPID2021-123616OB-I00

    Keywords

    • Centrifuge
    • fusion energy
    • high mirror
    • molten salt
    • stellarator

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