Formation process of tungsten nanostructure by the exposure to helium plasma under fusion relevant plasma conditions

Kajita, Shin; Sakaguchi, Wataru; Ohno, Noriyasu; Yoshida, N.; Saeki, Tsubasa

doi:10.1088/0029-5515/49/9/095005

Cited by 587 publications

(518 citation statements)

References 19 publications

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“…Synergistic effects of simultaneous irradiation of tungsten surfaces with He particles and high heat flux were observed for instance in [1,2]. The formation of surface and near-surface features with typical dimensions in the range of nanometres to micrometres under irradiation with He or H/He mixtures has been reported for tungsten from a number of plasma or high heat flux experiments [3,4,5]. The resulting morphology after irradiation with a H/He mixture is distinctly different form the morphology after irradiation with the pure species.…”

Section: Introductionmentioning

confidence: 92%

“…In the following we investigate two of these possible causes. The most obvious is the formation of a distorted surface layer, as shown in several experiments (see references [1][2][3][4][5][6][7][8][9][10][11]), which is investigated as a function of fluence and temperature in section 3.2.1. The second is the dependence of the sputtering yield on the crystal orientation.…”

Section: Investigation Of Possible Mechanismsmentioning

confidence: 99%

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Tungsten erosion under combined hydrogen/helium high heat flux loading

et al. 2014

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We investigated the erosion behaviour of tungsten under irradiation with a fusion reactorrelevant H/He mixture of 94%/6% at a power density of 10 MW/m². The investigated surface temperatures range up to 2000°C and the range of the applied fluence was up to 7×10 25 m -2 . The erosion yield we observe exceeds the value expected from physical sputtering data by a factor of 2. In addition we observe an Arrhenius-like increase of the erosion yield with temperature with an activation energy of 0.04 eV.

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Section: Introductionmentioning

confidence: 92%

Section: Investigation Of Possible Mechanismsmentioning

confidence: 99%

Tungsten erosion under combined hydrogen/helium high heat flux loading

et al. 2014

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“…An issue to be investigated further is whether such morphology changes will actually occur on plasma facing materials in fusion devices. It is known that the growth requires the surface temperature range of 1000 -2000 K and the incident ion energy, E i , of greater than 20 -30 eV [3]. Thus, detached plasmas, in which the temperature is lower than several eV [4], are thought to have an inhibiting effect on the growth of the fuzzy structure, because E i could be lower than the threshold energy.…”

Section: Pulsation Effects Of Incident Ion Energy On W Fuzz Growthmentioning

confidence: 99%

Pulsation Effects of Incident Ion Energy on W Fuzz Growth

Kajita

Kawaguchi

Hwangbo

et al. 2018

Plasma and Fusion Research

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Fuzzy nanostructure growth occurs on tungsten (W) surfaces by the exposure to helium (He) plasmas. We investigated pulsation effect in the incident energy of He ions on W fuzz growth. It is shown that He irradiation contributes to the growth of fuzzy layer even if the incident ion energy was less than the threshold energy of 20 -30 eV. When the duty cycle of the pulse was 1 -10 %, 7 -8 eV He ion irradiation have contributed to the fuzz growth in addition to high (> 60 eV) energy ion irradiation, and the growth rate was enhanced. . Because the layer significantly changes the material properties from those of bulk material, the influence on the transients in fusion devices accompanied by edge localized modes (ELMs) is one of the concerns [2]. An issue to be investigated further is whether such morphology changes will actually occur on plasma facing materials in fusion devices. It is known that the growth requires the surface temperature range of 1000 -2000 K and the incident ion energy, E i , of greater than 20 -30 eV [3]. Thus, detached plasmas, in which the temperature is lower than several eV [4], are thought to have an inhibiting effect on the growth of the fuzzy structure, because E i could be lower than the threshold energy. It is of importance to investigate the effects of transients such as ELMs, because they will convey higher energy particles even for a short period of time. Transient heating effects on fuzz growth have been investigated by Yu et al. using pulsed laser irradiation [5]; it was found that an enhanced fuzz growth was identified by transient heating events. In this study, we will investigate the effect of cyclic pulsation in E i on W fuzz growth.Experiments were conducted in the linear plasma device NAGDIS-II (Nagoya divertor simulator-II). He plasmas were produced in steady state, and a W sample (0.2 mm thick) was installed in the downstream of the cylindrical plasma; E i was controlled by biasing the sample using a bipolar power supply. The sample surface was in parallel to the magnetic field. Figure 1 (a) shows a schematic of the temporal evolution of E i . The incident ion energy was pulsated cyclically from E L (< 30 eV) to E H (65 -95 eV) at a frequency, f , of 10 or 100 Hz for 1 ms; the duty cycle, D, was 1 or 10 % at f = 10 or 100 Hz,

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“…Такая структура пуха имеет ряд положитель-ных качеств, таких как пониженный коэффициент распыления и большое тепловое излучение, прак-тически как у абсолютно чёрного тела, снижаю-щее температуру поверхности при тепловых на-грузках и повышающее стойкость поверхности к тепловым нагрузкам [8]. Поверхность со структу-рой пуха обладает большой удельной площадью, что имеет большое значение для адсорбции газов и катализа.…”

Section: планируемые работыunclassified

Plasma Device at Nru «mpei» for Testing of Refractory Metals and Creation of Highly Porous Materials of New Generation

Budaev¹,

Fedorovich²,

Lukashevsky³

et al. 2017

PAST-TF

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Плазменная установка НИУ «МЭИ» предназначена для испытаний тугоплавких металлов и создания высокопористых материа-лов нового поколения, в том числе для испытаний материалов в обеспечение отечественной программы создания термоядерно-го реактора (ТИН и ДЕМО) и международного термоядерного реактора ИТЭР. Установка представляет собой плазменную ло-вушку с линейной мультикасповой конфигурацией магнитного поля со стационарным плазменным разрядом с параметрами плазмы, обеспечивающими возможность мощной плазменно-тепловой нагрузки, ожидаемой на материалы в стационарных ре-жимах термоядерного реактора. В экспериментах планируется разработать новую технологию создания высокоразвитой и вы-сокопористой структуры поверхности тугоплавких металлов, в том числе так называемый вольфрамовый «пух» с размером пор и нановолокон ~50 нм, обладающих новыми физико-химическими свойствами, что представляет значительный интерес для ядерных, химических, энергетических, биомедицинских технологий.Ключевые слова: установки с магнитным удержанием плазмы, плазменно-тепловые испытания материалов, материалы термо-ядерного реактора, вольфрам, молибден, наноструктурированная поверхность, ИТЭР, нанотехнологии. The plasma device at NRU «MPEI» has been constructed for testing of refractory metals and creating high-porosity materials of a new generation for Russian thermonuclear reactors (FNS and DEMO) and the international thermonuclear experimental reactor ITER. The device is a plasma trap with a linear multi-casp configuration of the magnetic field, a stationary plasma discharge and plasma parameters, which make possible the powerful plasma-thermal load expected for materials in stationary modes of a thermonuclear reactor. In the experiments, it is planned to develop a new technology for creating a highly roughened and highly porous structure of the refractory metals surface, including so-called tungsten «fuzz» with pore size and nanofibers of ~50 nanometers and new physical and chemical properties, which is of considerable interest for nuclear, energy, biomedical technologies technologies. PLASMA DEVICE AT NRU «MPEI» FOR TESTING OF REFRACTORY METALS AND CREATION OF HIGHLY POROUS MATERIALS OF NEW GENERATIONKey words: fusion devices with magnetic confinement of plasma, high heat plasma test of materials, materials of fusion reactor, tungsten, molybdenum, nanostructured surface, ITER, nanotechnologies. : 10.21517/0202-3822-2017-40-3-23-36 DOI ВВЕДЕНИЕПри воздействии на материал экстремальных плазменно-тепловых нагрузок в последние годы обна-ружены эффекты стохастической кластеризации поверхности с иерархической гранулярностью (стати-стическим самоподобием -фрактальностью) и формирование высоко развитой поверхности, т.е. по-верхности с большой удельной площадью. Такая структура поверхности твёрдого тела наблюдается по-сле воздействия плазмы на материалы в термоядерных установках с магнитным удержанием плазмы и других плазменных установках с высокотемпературной плазмой [1, 2] при плазменно-тепловых испыта-

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Formation process of tungsten nanostructure by the exposure to helium plasma under fusion relevant plasma conditions

Cited by 587 publications

References 19 publications

Tungsten erosion under combined hydrogen/helium high heat flux loading

Tungsten erosion under combined hydrogen/helium high heat flux loading

Pulsation Effects of Incident Ion Energy on W Fuzz Growth

Plasma Device at Nru «mpei» for Testing of Refractory Metals and Creation of Highly Porous Materials of New Generation

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