Recent advances in characterising irradiation damage in tungsten for fusion power

Das, Suchandrima

doi:10.1007/s42452-019-1591-0

Cited by 26 publications

(14 citation statements)

References 128 publications

(217 reference statements)

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“…Further hydrogen and helium will diffuse from the plasma itself [3]. These processes have been shown to alter the material properties, resulting in hardening, embrittlement, creep and lattice swelling [1,2,[4][5][6][7]. Resultant residual stresses can act as offsets to other fatigue loading, potentially reducing fatigue life, which is likely to be the limiting factor for plant service life.…”

Section: Introductionmentioning

confidence: 99%

“…The combined effects must be better understood in order to develop ways to inhibit these changes in the design of power generating plants and to estimate the lifetime of functional plasma facing components. [1][2][3]7].…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, commonly used sample preparation methods, such as Focused Ion Beam (FIB) liftout procedures for producing transmission electron microscopy samples, risk modifying the surface layer [16,17]. Secondly, free surface effects begin to play a significant role in such a thin damage layer, resulting in a deviation from the behaviour expected in a bulk sample for a similar amount of damage [7,12,18]. This has led to the general approach of using significantly higher ion energies for measurements in order to circumvent the complications associated with low ion energy implantation (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Nanoscale lattice strains in self-ion implanted tungsten

Phillips

Das

et al. 2020

Acta Materialia

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Developing a comprehensive understanding of the modification of material properties by neutron irradiation is important for the design of future fission and fusion power reactors. Self-ion implantation is commonly used to mimic neutron irradiation damage, however an interesting question concerns the effect of ion energy on the resulting damage structures. The reduction in the thickness of the implanted layer as the implantation energy is reduced results in the significant quandary: Does one attempt to match the primary knock-on atom energy produced during neutron irradiation or implant at a much higher energy, such that a thicker damage layer is produced? Here we address this question by measuring the full strain tensor for two ion implantation energies, 2 MeV and 20 MeV in self-ion implanted tungsten, a critical material for the first wall and divertor of fusion reactors. A comparison of 2 MeV and 20 MeV implanted samples is shown to result in similar lattice swelling. Multi-reflection Bragg coherent diffractive imaging (MBCDI) shows that implantation induced strain is in fact heterogeneous at the nanoscale, suggesting that there is a non-uniform distribution of defects, an observation that is not fully captured by micro-beam Laue diffraction. At the surface, MBCDI and high-resolution electron back-scattered diffraction (HR-EBSD) strain measurements agree quite well in terms of this clustering/non-uniformity of the strain distribution. However, MBCDI reveals that the heterogeneity at greater depths in the sample is much larger than at the surface. This combination of techniques provides a powerful 1

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Nanoscale lattice strains in self-ion implanted tungsten

Phillips

Das

et al. 2020

Acta Materialia

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“…These cubes were positioned at a distance of 0.1 mm and represented the thickness of the filters utilized in each area. In addition, a 0.1 mm thick lead filter and a thin 0.1 mm thick tungsten target were chosen for the location where the photons pass and collide to be attenuated [29,30]. The input electron energy was assigned to 100 keV and the direction of the particles incident on the target was in the vertical direction to the Z axis.…”

Section: Methodsmentioning

confidence: 99%

Band pass filter plan in fluoroscopy for high energy range

et al. 2019

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In fluoroscopy, the absorption edge, the energy range, and the X-ray spectrum peak are the most important factors in filtration to obtain a proper image. Here, an experimental study was conducted to determine the filters that remove low-energy spectrums and attenuate high-energy ranges so that they cannot fundamentally affect image quality and diminish the absorbed dose by the patient. Considering the attenuation curves of proper elements besides accessibility and productivity issues, three elements were investigated that comprised Copper, Lead and Tin with diverse thicknesses in the X-ray energy range of 100 to 125 keV. Also, a simulation study by Monte Carlo N-Particle code was performed with an accuracy of 99%. The findings demonstrated that the use of a 0.1 mm lead filter retains the best image quality along with a significant reduction in the dose ratio obtained by raising milliampere. Multi or auxiliary filters require additional testing to achieve better image quality. In order to obtain the best possible X-ray band pass spectrum, the analysis of the attenuation and absorption profiles of the various elements plays an essential role in the calculation of the output intensities.

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“…These 1D He nanochannels that once interconnected to form a 3D network have a potential to outgas He outside of the material in Operando when the material is continuously being implanted with He particles, and thus, effectively reduce the net He particle flux received by the material. During these studies, He implantation has emerged as a useful tool for understanding complex and diverse environments, ranging from solar winds in space [8] to 'nanofuzz' formation in fusion energy systems [9]. This Special Issue, "Radiation Damage in Materials-Helium Effects", includes three review articles and nine full length papers (12 publications in total) on new irradiation material research activities and novel material ideas focused on understanding He effects on microstructure evolution and the subsequent properties.…”

mentioning

confidence: 99%

Special Issue: Radiation Damage in Materials—Helium Effects

Wang

Hattar

2020

Materials

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Despite its scarcity in terrestrial life, helium effects on microstructure evolution and thermo-mechanical properties can have a significant impact on the operation and lifetime of applications, including: advanced structural steels in fast fission reactors, plasma facing and structural materials in fusion devices, spallation neutron target designs, energetic alpha emissions in actinides, helium precipitation in tritium-containing materials, and nuclear waste materials. The small size of a helium atom combined with its near insolubility in almost every solid makes the helium–solid interaction extremely complex over multiple length and time scales. This Special Issue, “Radiation Damage in Materials—Helium Effects”, contains review articles and full-length papers on new irradiation material research activities and novel material ideas using experimental and/or modeling approaches. These studies elucidate the interactions of helium with various extreme environments and tailored nanostructures, as well as their impact on microstructural evolution and material properties.

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Recent advances in characterising irradiation damage in tungsten for fusion power

Cited by 26 publications

References 128 publications

Nanoscale lattice strains in self-ion implanted tungsten

Nanoscale lattice strains in self-ion implanted tungsten

Band pass filter plan in fluoroscopy for high energy range

Special Issue: Radiation Damage in Materials—Helium Effects

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