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Morphology Changes Due to Energetic Helium Ion Irradiation of Tungsten Surfaces at High Temperatures

2019
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Release : 2019
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Book Synopsis Morphology Changes Due to Energetic Helium Ion Irradiation of Tungsten Surfaces at High Temperatures by : Karla Brittany Hall

Download or read book Morphology Changes Due to Energetic Helium Ion Irradiation of Tungsten Surfaces at High Temperatures written by Karla Brittany Hall. This book was released on 2019. Available in PDF, EPUB and Kindle. Book excerpt: The Materials Irradiation Experiment (MITE-E) at the University of Wisconsin-Madison in the Inertial Electrostatic Confinement Laboratory was used to simulate helium ion (He+) irradiation of tungsten at fusion reactor relevant ion fluences and temperatures. Single and polycrystalline tungsten (SCW and PCW) samples were irradiated with 30-55 keV He+ at normal incidence with fluences of 3x1017 to 1019 He+/cm2 at temperatures from 500-900 oC. Post-irradiation analysis of the samples irradiated in the MITE-E device revealed several unique surface morphologies when the ion energy, temperature, and fluence were varied. Surface erosion due to energetic He+ irradiation was determined by mass loss measurements of samples pre- and post-irradiation. Past studies in the MITE-E revealed a surface orientation near {001} on PCW had considerably less erosion from He+ irradiation than surrounding grains Morphology development and mass loss measurements on [110] and [100] SCW revealed that the [100] crystal orientation lead to decreased surface erosion below 10^18 He+/cm2. Simulating what a fusion reactor component would likely experience, a sequentially increasing and decreasing multi-energy He+ irradiation on PCW was explored. Samples irradiated with increasing and decreasing multi-energy (35, 45, and 55 keV) He+ showed more surface damage than samples irradiated with mono-energetic (30 keV) He+. However, the multi-energy ion irradiated samples had less mass loss than the mono-energetic ion irradiated samples under similar parameters. Varying the temperature of samples under mono-energetic and multi-energy He+ irradiation at the same fluence caused an increase in mass loss as the temperature was decreased. The amount of mass loss and morphologies that developed on all samples point to He+ as a contributing mechanism in the undesired creation of W dust in a fusion reactor.

Characterization of the Dynamic Formation of Nano-tendril Surface Morphology on Tungsten While Exposed to Helium Plasma

2017
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Release : 2017
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Book Synopsis Characterization of the Dynamic Formation of Nano-tendril Surface Morphology on Tungsten While Exposed to Helium Plasma by : Kevin Benjamin Woller

Download or read book Characterization of the Dynamic Formation of Nano-tendril Surface Morphology on Tungsten While Exposed to Helium Plasma written by Kevin Benjamin Woller. This book was released on 2017. Available in PDF, EPUB and Kindle. Book excerpt: Tungsten undergoes surface morphology changes on the nanometer scale when subjected to low energy helium ion bombardment. This is due in part to the ion bombardment causing tungsten atoms to move on the surface, but also because of helium implantation and bubble development in the near surface at a depth 30 nm. At high enough surface temperatures, T/TM /~ 0.2, where TM is the melting temperature, nanoscale tendrils form on the surface and grow longer with additional bombardment by helium, but will decompose at the same temperature without helium bombardment. A tungsten surface that develops a densely packed layer of nano-tendrils over macroscopic areas greater than the grain size is referred to as tungsten fuzz, and is under intense study in fusion energy research, both for better understanding of how tungsten fuzz forms and of how tungsten fuzz affects the performance of plasma-facing components. The necessity of helium irradiation of the surface to induce nano-tendril growth motivates investigation into the dynamic process of helium implantation and accumulation in the surface. In this thesis, in situ elastic recoil detection is developed and used to measure the dynamic concentration of helium within a tungsten surface during the active growth of tungsten fuzz. During the development of in situ elastic recoil detection analysis, a variant of tungsten nano-tendril growth was discovered featuring drastically isolated bundles of nano-tendrils that grow at a higher rate than tungsten fuzz. The variation in nano-tendril morphology is correlated with incident helium ion energy modulation. The dependence on ion energy modulation and isolated nature of the nano-tendril bundles reveals clearly that nano-tendril growth is sensitive to surface kinetic effects. In this thesis, the structure and parameter space of the newly discovered nano-tendril bundle growth is analyzed with a suite of electron-based surface science techniques.

Improving the Materials Irradiation Xperimental Facility and Increasing Understanding of Helium Irradiation of Tungsten

2013
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Release : 2013
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Book Synopsis Improving the Materials Irradiation Xperimental Facility and Increasing Understanding of Helium Irradiation of Tungsten by :

Download or read book Improving the Materials Irradiation Xperimental Facility and Increasing Understanding of Helium Irradiation of Tungsten written by . This book was released on 2013. Available in PDF, EPUB and Kindle. Book excerpt: Minimizing damage to plasma facing components is a key issue that needs to be resolved before realizing commercial fusion reactors. The Materials Irradiation Experiment (MITE-E) at the University of Wisconsin Inertial Electrostatic Confinement (UW-IEC) Laboratory simulates fusion reactor conditions of light ion bombardment at high temperatures. Past experiments done in the MITE-E revealed that different morphologies developed on different grains of tungsten after irradiation with 30 keV helium ions at 900 oC. In this thesis, these structures have been correlated with the underlying crystal structure. Grains with orientations near {0 0 1} formed plateaus that were less eroded, while grains near {1 0 1} formed ripples parallel to 0 1 0. The connection of morphology to crystal orientation was made possible by the development of a new sample marking technique that allows the same location on a sample to be analyzed with the scanning electron microscope and the electron backscatter diffraction technique. It was also discovered that the sample pre-irradiation surface treatment has a large impact on the morphologies that develop after irradiation. A sample irradiated with helium ions over a spectrum of energies developed a more damaged surface structure than samples irradiated to the same fluence with mono-energetic helium. The sample with multiple energy implantation did not develop blisters, which had been seen previously on mono-energetically implanted samples in the MITE-E. In a separate experiment, samples of ZrB2, made with isotopically separated 11B, were irradiated with 30 keV helium ions in the MITE-E, and the results were compared to other materials irradiated under similar conditions. The rates and levels of damage observed on all samples would have a significant impact on fusion reactor divertor plates and first walls.

Surface Response of Tungsten to Helium and Hydrogen Plasma Flux as a Function of Temperature and Incident Kinetic Energy

2013
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Book Synopsis Surface Response of Tungsten to Helium and Hydrogen Plasma Flux as a Function of Temperature and Incident Kinetic Energy by : Faiza Sefta

Download or read book Surface Response of Tungsten to Helium and Hydrogen Plasma Flux as a Function of Temperature and Incident Kinetic Energy written by Faiza Sefta. This book was released on 2013. Available in PDF, EPUB and Kindle. Book excerpt: Tungsten is a leading candidate material for the diverter in future nuclear fusion reactors. Previous experiments have demonstrated that surface defects and bubbles form in tungsten when ex- posed to helium and hydrogen plasmas, even at modest ion energies. In some regimes, between 1000K and 2000K, and for He energies below 100eV, "fuzz" like features form. The mechanisms leading to these surfaces comprised of nanometer sized tungsten tendrils which include visible helium bubbles are not currently known. The role of helium bubble formation in tendril morphology could very likely be the starting point of these mechanisms. Using Molecular dynamics (MD) simulations, the role of helium and hydrogen exposure in the initial formation mechanisms of tungsten "fuzz" are investigated. Molecular dynamics simulations are well suited to describe the time and length scales associated with initial formation of helium clusters that eventually grow to nano-meter sized helium bubbles. MD simulations also easily enable the modeling of a variety of surfaces such as single crystals, grain boundaries or "tendrils". While the sputtering yield of tungsten is generally low, previous observations of surface modification due to plasma exposure raise questions about the effects of surface morphology and sub-surface helium bubble populations on the sputtering behavior. Results of computational molecular dynamics are reported that investigate the influence of sub-surface helium bubble distributions on the sputtering yield of tungsten (100) and (110) surfaces induced by helium ion exposure in the range of 300 eV to 1 keV. The calculated sputtering yields are in reasonable agreement with a wide range of experimental data; but do not show any significant variation as a result of the pre-existing helium bubbles. Molecular dynamics simulations reveal a number of sub-surface mechanisms leading to nanometer- sized "fuzz" in tungsten exposed to low-energy helium plasmas. We find that during the bubble formation process, helium clusters create self-interstitial defect clusters in tungsten by a trap mutation process, followed by the migration of these defects to the surface that leads to the formation of layers of adatom islands on the tungsten surface. As the helium clusters grow into nanometer sized bubbles, their proximity to the surface and extremely high gas pressures can cause them to rupture the surface thus enabling helium release. Helium bubble bursting induces additional surface damage and tungsten mass loss which varies depending on the nature of the surface. We then show tendril-like geometries have surfaces that are more resilient to helium clustering and bubble formation and rupture. Finally, the study includes hydrogen to reveal the effect of a mixed 90%H-10%He plasma mix on the tungsten surface. We find that hydrogen greatly affects the tungsten surface, with a near surface hydrogen saturation layer, and that helium clusters still form and are attractive trapping sites for hydrogen. Molecular dynamics simulations have also investigated the effect of sub-surface helium bubble evolution on tungsten surface morphology. The helium bubble/tungsten surface interaction has been systematically studied to determine how parameters such as bubble shape and size, temperature, tungsten surface orientation and ligament thickness above the bubble impact bubble stability and surface evolution. The tungsten surface is roughened by a combination of adatom islands, craters and pinholes. The study provides insight into the mechanisms and conditions leading to various tungsten topology changes, most notably the formation of nanoscale fuzz. An atomistic study of the mechanisms behind initial phases of tungsten nano-fuzz growth has determined that tungsten surfaces are affected by sub-displacement energy helium and hydrogen fluxes through a series of mechanisms. Sub-surface helium atom clustering, bubble nucleation, growth and rupture lead to tungsten surface deformation. Helium clustering processes vary near grain boundaries or in tendril-like surface geometries. In the presence of hydrogen, these mechanisms are coupled with hydrogen surface saturation. Finally, further investigation to connect these atomistic mechanisms to nano-size tungsten fuzz growth is needed to get a comprehensive under- standing of the effects of low energy helium and hydrogen on tungsten.

The Effects of Tungsten's Pre-irradiation Surface Condition on Helium-irradiated Morphology

2015
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Release : 2015
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Book Synopsis The Effects of Tungsten's Pre-irradiation Surface Condition on Helium-irradiated Morphology by :

Download or read book The Effects of Tungsten's Pre-irradiation Surface Condition on Helium-irradiated Morphology written by . This book was released on 2015. Available in PDF, EPUB and Kindle. Book excerpt: Erosion is a concern associated with the use of tungsten as a plasma-facing component in fusion reactors. To compare the damage progression, polycrystalline tungsten (PCW) and (110) single crystal tungsten (SCW) samples were prepared with (1) a mechanical polish (MP) with roughness values in the range of 0.018-0.020 [mu]m and (2) an MP and electropolish (MPEP) resulting in roughness values of 0.010-0.020 [mu]m for PCW and 0.003-0.005 [mu]m for SCW samples. Samples were irradiated with 30 keV He+ at 1173 K to fluences between 3 × 1021 and 6 × 1022 He/m2. The morphologies that developed after low-fluence bombardment were different for each type of sample--MP SCW, MPEP SCW, MP PCW, and MPEP PCW. At the highest fluence, the SCW MPEP sample lost significantly more mass and developed a different morphology than the MP SCW sample. The PCW samples developed a similar morphology and had similar mass loss at the highest fluence. Surface preparation can have a significant effect on post-irradiation morphology that should be considered for the design of future fusion reactors such as ITER and DEMO.

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