Hydrogen isotope transport across tungsten surfaces exposed to a fusion relevant He ion fluence

Baldwin, M.J.; Doerner, R. P.

doi:10.1088/1741-4326/aa70b1

Cited by 42 publications

(18 citation statements)

References 36 publications

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“…Doerner 2 , C. Xu 4 , J.P. Zhu 4 and E.G. Fu 4,a It is thought that this is caused by the so-called barrier effect in which the implanted He ions form a thin (few tens of nm) He nanobubble layer in the sample and act to reduce the D retention either via the formation of interconnected pathways to the sample surface, leading the D ions to diffuse back to the plasma and resulting in the D retention decreasing, or by the formation of a diffusion barrier to the D atoms, or both [6]. On the other hand, many studies [7][8][9][10][11] have shown that radiation damage in W induced e.g.…”

Section: Nuclear Fusionmentioning

confidence: 99%

Reduced D trapping by plasma-implanted He nanobubbles in radiation damaged tungsten

Bai

Zheng

et al. 2019

Nucl. Fusion

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The presence of a plasma-implanted helium nanobubble layer significantly reduces deuterium (D) retention in undamaged commercial ITER grade tungsten (W). In this paper, we show evidence that this phenomenon can survive displacement damage. A He plasma exposure (sample temperature 643 K, ion flux 10 22 m −2 s −1 at 100 eV, fluence 10 25 m −2 ) pre-treatment was performed to create a thin He nanobubble layer in the first ~15 nm of ITER grade W samples. Samples were then irradiated by 5 MeV Cu ions at room temperature to create 0.001 to 0.1 dpa with peak damage rates occurring about 860 nm below the sample surface. Samples without He plasma exposure pre-treatment were also irradiated by 5 MeV Cu ions to provide a controlled baseline. All samples were subsequently exposed to D plasma at 373 K to a fluence of 10 24 m −2 . Nuclear reaction analysis results show that across a range of peak dpa ranging from 0.001 to 0.1 dpa, D retention inventory in the samples with He plasma exposure pre-treatment is reduced by a factor of two compared to samples without He plasma exposure pre-treatment. Transmission electron microscopy directly showed a surviving nanobubble layer after 0.1 dpa damage. However, the thickness of the bubble layer appears to have been reduced. The results suggest that the plasma-implanted He nanobubble layer can survive radiation damage and still function to reduce D diffusion and retention in tungsten-based plasma facing components.

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Section: Nuclear Fusionmentioning

confidence: 99%

Reduced D trapping by plasma-implanted He nanobubbles in radiation damaged tungsten

Bai

Zheng

et al. 2019

Nucl. Fusion

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“…11,12 Furthermore, the research on the retention of hydrogen and isotopes on the surface holds significant potential for nuclear fusion energy. 13,14 Tokamak reactors commonly employ hydrogen and isotopes as fuel sources, and the interaction of these species in the plasma state on the inner walls of the reactor has garnered significant attention in current studies. 15−18 Moreover, hydrogen storage assisted by plasma has garnered attention from several research groups.…”

Section: Introductionmentioning

confidence: 99%

“…H 2 and D 2 are commonly applied to passivate Si substrates in the microelectronic industry to prevent contamination, such as H 2 O, which is present in the base pressure of standard vacuum vessels. − Additionally, passivation finds various applications in thin film technologies, serving as anticorrosive protection and interface functionalization and creating hard coatings. − Passivation of dangling bonds is crucial in hydrogenated amorphous silicon materials. , Furthermore, the research on the retention of hydrogen and isotopes on the surface holds significant potential for nuclear fusion energy. , Tokamak reactors commonly employ hydrogen and isotopes as fuel sources, and the interaction of these species in the plasma state on the inner walls of the reactor has garnered significant attention in current studies. − Moreover, hydrogen storage assisted by plasma has garnered attention from several research groups. , To control the physical–chemical mechanisms of passivation, factors like the surface state, temperature, and sticking coefficient must be taken into consideration. − …”

Section: Introductionmentioning

confidence: 99%

Comparative Passivation of Si(100) by H₂ and D₂ Atmospheres under Simultaneous Xe⁺ Bombardment: An X-ray Photoelectron Spectroscopy Analysis

Antunes,

Jimenez,

Cemin

et al. 2024

Langmuir

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This study presents a comparison of H 2 and D 2 passivation on Si(100) under simultaneous Xe + ion bombardment. The impact of Xe + ions causes significant damage to the substrate surface, leading to an increase in H 2 (D 2 ) retention as Si−H (Si−D) bonds. The ion bombardment conditions are precisely controlled using a Kaufman ion gun. The atomic concentrations on the surface of the sample were investigated by quasi-in situ X-ray photoelectron spectroscopy. A simple methodology is employed to estimate the H (D) chemical concentration and the cover ratio of the sample, with regard to the oxygen concentration through residual water chemisorption present in the vacuum vessel. Differences in passivation are expected when using H 2 or D 2 atmospheres because their retained scission energies and physisorption properties differ. The results indicate an increase of the sticking coefficient for D 2 and H 2 under the ion bombardment. It is also found that the flux of H 2 (D 2 ) impinging on the surface contributes to play an important role in the whole process. Finally, a model is proposed to describe the phenomenon of the passivation of Si under Xe + ion bombardment in the presence of H 2 (D 2 ).

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“…Therefore, it seems obvious that the retention of hydrogen isotopes should closely follow the evolution of damage with the dose. However, hydrogen isotopes retention is a complicated phenomenon because it is the result of many different parameters such as the material grade (structure and impurity level) [24], the material temperature [25], surface condition [26], and it depends critically on the incoming particle flux, its energy and composition as hydrogen bubble formation occurs above a certain solute concentration [27,28]. Eventually, macroscopic defects, such as blisters, develop [24,[29][30][31][32].…”

Section: Introductionmentioning

confidence: 99%

A critical review of experiments on deuterium retention in displacement-damaged tungsten as function of damaging dose

Schwarz-Selinger

2023

Mater. Res. Express

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Experimental results from the literature on the evolution of deuterium retention in displacement-damaged tungsten as a function of damaging dose are presented. Except for a few outliers, retention is generally found to increase with the presence of displacement damage. However, total retention results scatter by three orders of magnitude for similar exposure temperatures and are difficult to compare, because they depend on experiment-specific parameters such as the irradiation energy used to produce the displacement damage or the deuterium exposure parameters such as fluence. Even local deuterium concentration measurements were found to scatter by more than one order of magnitude. An experimental methodology is proposed that allows robust conclusions about the evolution of deuterium retention with damage dose and the results are discussed in detail. Recrystallized tungsten is irradiated with 20.3 MeV self-ions at room temperature with different damage doses ranging from 0.001 to 2.3 displacements per atom. The defects are then decorated with a low flux, low-energy deuterium plasma at 450 K sample temperature. 3He Nuclear Reaction Analysis (NRA) shows that the deuterium concentration levels off from the linear increase already at very low damage dose of about 0.005 dpa. At a damage dose of 0.23 dpa a maximum deuterium concentration of about 1.4 at% is reached. Thermal Desorption Spectroscopy (TDS) shows that with damage increasing above 0.005 dpa, the overall shape of the desorption spectra does not change substantially, only their intensities increase. Total amounts derived from TDS are in quantitative agreement with results from 3He-NRA. Experimental results following this methodology also agree quantitatively with very recent parameter-free modeling of damage evolution.

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Hydrogen isotope transport across tungsten surfaces exposed to a fusion relevant He ion fluence

Cited by 42 publications

References 36 publications

Reduced D trapping by plasma-implanted He nanobubbles in radiation damaged tungsten

Reduced D trapping by plasma-implanted He nanobubbles in radiation damaged tungsten

Comparative Passivation of Si(100) by H₂ and D₂ Atmospheres under Simultaneous Xe⁺ Bombardment: An X-ray Photoelectron Spectroscopy Analysis

A critical review of experiments on deuterium retention in displacement-damaged tungsten as function of damaging dose

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Hydrogen isotope transport across tungsten surfaces exposed to a fusion relevant He ion fluence

Cited by 42 publications

References 36 publications

Reduced D trapping by plasma-implanted He nanobubbles in radiation damaged tungsten

Reduced D trapping by plasma-implanted He nanobubbles in radiation damaged tungsten

Comparative Passivation of Si(100) by H2 and D2 Atmospheres under Simultaneous Xe+ Bombardment: An X-ray Photoelectron Spectroscopy Analysis

A critical review of experiments on deuterium retention in displacement-damaged tungsten as function of damaging dose

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Comparative Passivation of Si(100) by H₂ and D₂ Atmospheres under Simultaneous Xe⁺ Bombardment: An X-ray Photoelectron Spectroscopy Analysis