8 research outputs found
Overview of processing technologies for tungsten-steel composites and FGMs for fusion applications
Tungsten is a prime candidate material for the plasma-facing components in future fusion devices, e.g.
ITER and DEMO. Because of the harsh and complex loading conditions and the differences in material properties,
joining of the tungsten armor to the underlying construction and/or cooling parts is a complicated issue.
To alleviate the thermal stresses at the joint, a sharp interface may be replaced by a gradual one with a smoothly
varying composition. In this paper, several techniques for the formation of tungsten-steel composites and graded
layers are reviewed. These include plasma spraying, laser cladding, hot pressing and spark plasma sintering.
Structure, composition and selected thermal and mechanical properties of representative layers produced by
each of these techniques are presented. A summary of advantages and disadvantages of the techniques and an
assessment of their suitability for the production of plasma-facing components is provided
Embedment of ZnO nanoparticles in SiO2 by ion implantation and low-temperature oxidation
Samples of silica glass (SiO2) implanted with 60 keV Zn ions to a fluence of 1.0x10(17) ions/cm(2) were annealed in oxygen gas to form ZnO nanoparticles (NPs). Although the ZnO NPs were formed mainly on the SiO2 surface after oxidation at 700 degrees C for 1 h, they were formed inside the SiO2 substrate after lower temperature and long-duration oxidation at 500 degrees C for similar to 70 h, i.e., the embedment of ZnO NPs in SiO2 was attained. The embedded NPs show a slightly stronger exciton peak and much weaker defect luminescence than the NPs formed on the surface. (c) 2007 American Institute of Physics
Recent progress in research on tungsten materials for nuclear fusion applications in Europe
The current magnetic confinement nuclear fusion power reactor concepts going beyond ITER are based on assumptions about the availability of materials with extreme mechanical, heat, and neutron load capacity. In Europe, the development of such structural and armour materials together with the necessary production, machining, and fabrication technologies is pursued within the EFDA long-term fusion materials programme. This paper reviews the progress of work within the programme in the area of tungsten and tungsten alloys. Results, conclusions, and future projections are summarized for each of the programme's main subtopics, which are: (1) fabrication, (2) structural W materials, (3) W armour materials, and (4) materials science and modelling. It gives a detailed overview of the latest results on materials research, fabrication processes, joining options, high heat flux testing, plasticity studies, modelling, and validation experiments. © 2012 Elsevier B.V. All rights reserved
A brief summary of the progress on the EFDA tungsten materials program
The long-term objective of the European Fusion Development Agreement (EFDA) fusion materials programme is to develop structural and armor materials in combination with the necessary production and fabrication technologies for reactor concepts beyond the International Thermonuclear Experimental Reactor. The programmatic roadmap is structured into four engineering research lines which comprise fabrication process development, structural material development, armor material optimization, and irradiation performance testing, which are complemented by a fundamental research programme on "Materials Science and Modeling." This paper presents the current research status of the EFDA experimental and testing investigations, and gives a detailed overview of the latest results on materials research, fabrication, joining, high heat flux testing, plasticity studies, modeling, and validation experiments
Recent progress in research on tungsten materials for nuclear fusion applications in Europe
The current magnetic confinement nuclear fusion power reactor concepts going beyond ITER are based on assumptions about the availability of materials with extreme mechanical, heat, and neutron load capacity. In Europe, the development of such structural and armour materials together with the necessary production, machining, and fabrication technologies is pursued within the EFDA long-term fusion materials programme. This paper reviews the progress of work within the programme in the area of tungsten and tungsten alloys. Results, conclusions, and future projections are summarized for each of the programme's main subtopics, which are: (1) fabrication, (2) structural W materials, (3) W armour materials, and (4) materials science and modelling. It gives a detailed overview of the latest results on materials research, fabrication processes, joining options, high heat flux testing, plasticity studies, modelling, and validation experiments. © 2012 Elsevier B.V. All rights reserved