Physics and technology considerations for the deuterium–tritium fuel cycle and conditions for tritium fuel self sufficiency

Abdou, Mohamed; Riva, M.; Ying, Alice; Day, Christian; Loarte, A.; Baylor, L. R.; Humrickhouse, Paul W.; Fuerst, Thomas F.; Cho, Seungyon

doi:10.1088/1741-4326/abbf35

Cited by 96 publications

(95 citation statements)

References 195 publications

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“…A major issue for both tokamaks and stellarators is the production of adequate tritium in the blanket [27]. As discussed in [3], stellarators have properties that better address a number of the tritium selfsufficiency issues:…”

Section: Unlike Tokamaks Coils That Allow Open Accessmentioning

confidence: 99%

Carbon Dioxide, Fusion, and Stellarators

Boozer¹

2021

Preprint

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Much emotion is expended on the dangers of carbon dioxide, but solutions require reason and recognition of facts: (1) The cost of developing options is approximately a thousand times less than their deployment. (2) Timescales involve two questions: (a) How quickly can an option be demonstrated? (b) How quickly can the required equivalent of thousands of units be built. Two questions are implied: (1) What options would most fundamentally change the carbon-dioxide problem? (2) For each option, how could it be demonstrated most quickly? An option of fundamental importance is direct air capture of carbon dioxide. The option that appears most attractive for carbon-free energy production is the stellarator fusion concept, which is poised for a rapid demonstration.

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Section: Unlike Tokamaks Coils That Allow Open Accessmentioning

confidence: 99%

Carbon Dioxide, Fusion, and Stellarators

Boozer¹

2021

Preprint

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“…A number of the scientific issues are given in a Nuclear Fusion tokamak-focused review of the deuterium-tritium fusion cycle [5]. This review had a summarizing statement: "A primary conclusion of this paper is that the physics and technology state of the art will not enable DEMO and future power plants to satisfy these principal requirements."…”

Section: A Deuterium-tritium Issuesmentioning

confidence: 99%

“…1. Tritium breeding ratio (TBR) Page 7 of the DT fusion cycle review [5] notes: "Physics requirements on the blanket in future fusion systems, such as presence of non-breeding materials for stabilizing shells, penetrations for heating, current drive, and other purposes, are not yet firmly established and can result in a substantial reduction in the achievable TBR. "…”

Section: A Deuterium-tritium Issuesmentioning

confidence: 99%

“…The adequate mitigation of disruptions and runaway electrons for ITER to achieve its mission is extremely challenging [6], but they must be essentially eliminated for a power plant to be feasible [5,7].…”

Section: A Deuterium-tritium Issuesmentioning

confidence: 99%

“…Page 13 of the DT fusion cycle review [5] notes: "burn fraction and fueling efficiency represent dominant parameters toward realizing tritium self-sufficiency. "…”

Section: Burn Fraction and Fueling Efficiencymentioning

confidence: 99%

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Stellarators as a Fast Path to Fusion

Boozer

2021

Preprint

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The enhancement of the atmospheric concentration of carbon dioxide is doubling every forty years. Options must be developed for energy production that do not drive carbon-dioxide emissions and can be fully deployed within a few doubling times. Unit size and cost of electricity are only relevant in comparison to alternative worldwide energy solutions. Intermittency, site specificity, waste management, and nuclear proliferation make fusion attractive as the basis for a carbon-free energy system compared to the alternatives. Nonetheless, fusion will not be an option for deployment until a power plant has successfully operated. A critical element in a minimal time and risk program to operate a fusion power plant is the use of computational design as opposed to just extrapolation. The importance of minimizing time and risk is so great that ideally more than one concept would be pursued. Unfortunately, only the stellarator has an empirical demonstration of the reliability of computational design through large changes in configuration properties and scale. The cost of computational design is extremely small, even compared to the present scale of the fusion program. Adequate time for the development of ideas that increase attractiveness and reduce risks requires a quick initiation of design studies of fusion power plants, but this is counterbalanced by the natural resistance to change. As will be shown, that sentiment is contrary to both the needs of society and the status of the science; a shift in the priorities of the fusion program to societal needs is required. The construction cost of a power plant may seem great relative to the risk, but a fusion program of tens of billions of dollars a year would be approximately one percent of the annualized financial benefit of success.

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Nuclear Technology, 4. Nuclear Fusion

Zohm,

Schumacher,

Herold

2023

Ullmann's Encyclopedia of Industrial Chemistry

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The article contains sections titled: 1 Introduction 2 Fusion Physics 3 Plasma Confinement and Status of Fusion Research 3.1 Magnetic Plasma Confinement 3.1.1 Tokamak 3.1.2 Stellarator 3.1.3 Status of Magnetic Confinement Fusion 3.2 Inertial Confinement Fusion 4 Fusion Power Plant Technology 4.1 Vacuum Vessel and First Wall 4.2 Magnets 4.3 Plasma Heating 4.4 Breeding Blanket and Fuel Cycle References

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Physics and technology considerations for the deuterium–tritium fuel cycle and conditions for tritium fuel self sufficiency

Cited by 96 publications

References 195 publications

Carbon Dioxide, Fusion, and Stellarators

Carbon Dioxide, Fusion, and Stellarators

Stellarators as a Fast Path to Fusion

Nuclear Technology, 4. Nuclear Fusion

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