Multimodal options for materials research to advance the basis for fusion energy in the ITER era

Zinkle, S.J.; Möslang, A.; Muroga, T.; Tanigawa, Hiroyasu

doi:10.1088/0029-5515/53/10/104024

Cited by 76 publications

(39 citation statements)

References 117 publications

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“…These steels are expected to exhibit low-temperature embrittlement problems, but, on the positive side, their high density of nano-scale precipitates and microstructures are predicted, on physical metallurgy grounds, to lead to superior performance to EUROFER on low temperature and helium embrittlement [67]. This prediction also holds for ODS steels [eg.…”

Section: High Temperature Ferritic-martensitic Steelsmentioning

confidence: 99%

Developing structural, high-heat flux and plasma facing materials for a near-term DEMO fusion power plant: The EU assessment

Stork

Agostini

Boutard

et al. 2014

Journal of Nuclear Materials

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217

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The findings of the EU 'Materials Assessment Group' (MAG), within the 2012 EU Fusion Roadmap exercise, are discussed. MAG analysed the technological readiness of structural, plasma facing and high heat flux materials for a DEMO concept to be constructed in the early 2030s, proposing a coherent strategy for R&D up to a DEMO construction decision.A DEMO phase I with a 'Starter Blanket' and 'Starter Divertor' is foreseen: the blanket being capable of withstanding ≥2MW.yr.m -2 fusion neutron fluence (~20 dpa in the frontwall steel). A second phase ensues for DEMO with ≥5MW.yr.m -2 first wall neutron fluence.Technical consequences for the materials required and the development, testing and modelling programmes, are analysed using: a systems engineering approach, considering reactor operational cycles, efficient maintenance and inspection requirements, and interaction § Corresponding author. Address as 1. email: derek.stork@btinternet.com *Manuscript Click here to view linked References with functional materials/coolants; and a project-based risk analysis, with R&D to mitigate risks from material shortcomings including development of specific risk mitigation materials.The DEMO balance of plant constrains the blanket and divertor coolants to remain unchanged between the two phases. The blanket coolant choices (He gas or pressurised water) put technical constraints on the blanket steels, either to have high strength at higher temperatures than current baseline variants (above 650ºC for high thermodynamic efficiency from He-gas coolant), or superior radiation-embrittlement properties at lower temperatures (~290-320ºC), for construction of water-cooled blankets. Risk mitigation proposed would develop these options in parallel, and computational and modelling techniques to shorten the cycle-time of new steel development will be important to achieve tight R&D timescales. The superior power handling of a water-cooled divertor target suggests a substructure temperature operating window (~200-350ºC) that could be realised, as a baseline-concept, using tungsten on a copper-alloy substructure. The difficulty of establishing design codes for brittle tungsten puts great urgency on the development of a range of advanced ductile or strengthened tungsten and copper compounds.Lessons learned from Fission reactor material development have been included, especially in safety and licensing, fabrication/joining techniques and designing for in-vessel inspection. The technical basis of using the ITER licensing experience to refine the issues in nuclear testing of materials is discussed.Testing with 14MeV neutrons is essential to Fusion Materials development, and the Roadmap requires acquisition of ≥30 dpa (steels) 14MeV test data by 2026. The value and limits of pre-screening testing with fission neutrons on isotopically-or chemically-doped steels and with ion-beams are evaluated to help determine the minimum14 MeV testing programme requirements.

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Section: High Temperature Ferritic-martensitic Steelsmentioning

confidence: 99%

Developing structural, high-heat flux and plasma facing materials for a near-term DEMO fusion power plant: The EU assessment

Stork

Agostini

Boutard

et al. 2014

Journal of Nuclear Materials

Self Cite

217

135

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“…A review by Zinkle et al has shown the development of materials with point defect sink strengths above ~10 16 m -2 can significantly suppress several of the radiation-induced processes seen in nuclear materials, such as radiation-induced hardening [3]. Such studies have shown the importance of the sink density to irradiation resistance, particularly when high dose applications are desired.…”

Section: Numerous Light Water Reactor (Lwr) Nuclear Power Plants In Tmentioning

confidence: 99%

Defect sink characteristics of specific grain boundary types in 304 stainless steels under high dose neutron environments

et al. 2015

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Radiation induced segregation (RIS) is a well-studied phenomena which occurs in many structurally relevant nuclear materials including austenitic stainless steels. RIS occurs due to solute atoms preferentially coupling with mobile point defect fluxes that migrate and interact with defect sinks. Here, a 304 stainless steel was neutron irradiated up to 47.1 dpa at 320°C. Investigations into the RIS response at specific grain boundary types were utilized to determine the sink characteristics of different boundary types as a function of irradiation dose. A rate theory model built on the foundation of the modified inverse Kirkendall (MIK) model is proposed and benchmarked to the experimental results. This model, termed the GiMIK model, includes alterations in the boundary conditions based on grain boundary structure and expressions for interstitial binding. This investigation, through experiment and modeling, found specific grain boundary structures exhibit unique defect sink characteristics depending on their local structure. Such interactions were found to be consistent across all doses investigated and to have larger global implications, including precipitation of Ni-Si clusters near different grain boundary types.

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“…Even though some classes of steels and other metal alloys are known to have high radiation tolerance, their properties do start to change immediately after the onset of irradiation [10,13]. This has motivated an intense ongoing search for new classes of materials with improved radiation hardness.…”

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confidence: 99%

Mechanism of Radiation Damage Reduction in Equiatomic Multicomponent Single Phase Alloys

et al. 2016

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Recently a new class of metal alloys, of single-phase multicomponent composition at roughly equal atomic concentrations ("equiatomic"), have been shown to exhibit promising mechanical, magnetic, and corrosion resistance properties, in particular, at high temperatures. These features make them potential candidates for components of next-generation nuclear reactors and other high-radiation environments that will involve high temperatures combined with corrosive environments and extreme radiation exposure. In spite of a wide range of recent studies of many important properties of these alloys, their radiation tolerance at high doses remains unexplored. In this work, a combination of experimental and modeling efforts reveals a substantial reduction of damage accumulation under prolonged irradiation in single-phase NiFe and NiCoCr alloys compared to elemental Ni. This effect is explained by reduced dislocation mobility, which leads to slower growth of large dislocation structures. Moreover, there is no observable phase separation, ordering, or amorphization, pointing to a high phase stability of this class of alloys.

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Multimodal options for materials research to advance the basis for fusion energy in the ITER era

Cited by 76 publications

References 117 publications

Developing structural, high-heat flux and plasma facing materials for a near-term DEMO fusion power plant: The EU assessment

Developing structural, high-heat flux and plasma facing materials for a near-term DEMO fusion power plant: The EU assessment

Defect sink characteristics of specific grain boundary types in 304 stainless steels under high dose neutron environments

Mechanism of Radiation Damage Reduction in Equiatomic Multicomponent Single Phase Alloys

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