Direct observation of hydrogen permeation through grain boundaries in tungsten

Díaz-Rodríguez, Pablo; Panizo-Laiz, M.; González, César; Rodríguez, Iglesias; Martín-Bragado, Ignacio; González-Arrabal, R.; Perlado, J.M.; Peña‐Rodríguez, Ovidio; Rivera, Alejandro

doi:10.1007/s42247-021-00344-w

Cited by 6 publications

(2 citation statements)

References 56 publications

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“…They developed advanced plasma diagnostics [202] based on laser-driven radiation and particle sources and use them for studying new extreme states of matter [192][193][194][203][204][205][206][207][208][209] . European scientists contribute with new ideas and development to the specific IFE challenges appearing when studying advanced nanostructured materials for the first wall [210,211] , analysing the first-wall damage by light species accumulation [122,[212][213][214][215][216][217] , developing coatings against corrosion [124][125][126] , studying the neutronic transport, materials activation and damage and proposing an integral layout for IFE reactors. Extensive collaboration is established in this area with programmes on IFE [218] in the United States and Japan, the High Average Power Lasers Program (HAPL) in the United States and with magnetic European fusion in common areas, such as structural materials, cooling and tritium breeding.…”

Section: The Icf Community and Its Competencesmentioning

confidence: 99%

Future for inertial-fusion energy in Europe: a roadmap

Batani,

Colaïtis,

Consoli

et al. 2023

High Pow Laser Sci Eng

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The recent achievement of fusion ignition with laser-driven technologies at the National Ignition Facility sets a historic accomplishment in fusion energy research. This accomplishment paves the way for using laser inertial fusion as a viable approach for future energy production. Europe has a unique opportunity to empower research in this field internationally, and the scientific community is eager to engage in this journey. We propose establishing a European programme on inertial-fusion energy with the mission to demonstrate laser-driven ignition in the direct-drive scheme and to develop pathway technologies for the commercial fusion reactor. The proposed roadmap is based on four complementary axes: (i) the physics of laser–plasma interaction and burning plasmas; (ii) high-energy high repetition rate laser technology; (iii) fusion reactor technology and materials; and (iv) reinforcement of the laser fusion community by international education and training programmes. We foresee collaboration with universities, research centres and industry and establishing joint activities with the private sector involved in laser fusion. This project aims to stimulate a broad range of high-profile industrial developments in laser, plasma and radiation technologies along with the expected high-level socio-economic impact.

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Section: The Icf Community and Its Competencesmentioning

confidence: 99%

Future for inertial-fusion energy in Europe: a roadmap

Batani,

Colaïtis,

Consoli

et al. 2023

High Pow Laser Sci Eng

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“…In 2022, Diaz-Rodriguez et al [ 43 ] studied hydrogen permeation along grain boundaries in nanostructured tungsten deposited on nickel substrate. Their permeation measurements at 520–705 K (247–432 °C) resulted in PRF ~ 4 at all temperatures.…”

Section: Recent Advances In Hydrogen Permeation Barriersmentioning

confidence: 99%

Recent Advances and Prospects in Design of Hydrogen Permeation Barrier Materials for Energy Applications—A Review

2022

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The hydrogen infrastructure involves hydrogen production, storage and delivery for utilization with clean energy applications. Hydrogen ingress into structural materials can be detrimental due to corrosion and embrittlement. To enable safe operation in applications that need protection from hydrogen isotopes, this review article summarizes most recent advances in materials design and performance characterization of barrier coatings to prevent hydrogen isotopes’ absorption ingress and permeation. Barriers are crucial to prevent hydride formation and unwanted hydrogen effects to increase safety, materials’ lifetime and reduce cost for applications within nuclear and renewable energy. The coating may be applied on a material that requires protection from hydrogen pick-up, transport and hydride formation in hydrogen storage containers, in pipelines, spent nuclear fuel storage or in nuclear reactors. While existing, commercial coatings that have been much in use may be satisfactory for various applications, it is desirable to evaluate whether alternative coating concepts can provide a greater resistance to hydrogen isotope permeation along with other improved properties, such as mechanical strength and thermal resistance. The information presented here is focusing on recent findings within the past 5–7 years of promising hydrogen barriers including oxides, nitrides, carbon, carbide, MAX-phases and metals and their mechanical strength, hydrogen pick-up, radiation resistance and coating manufacturing techniques. A brief introduction to hydrogen permeation is provided. Knowledge gaps were identified to provide guidance for material’s research prospects.

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