The effects of ion species and target temperature on topography development on ion bombarded Si

Carter, G.; Vishnyakov, Vladimir; Martynenko, Yu. V.; Nobes, M. J.

doi:10.1063/1.359931

Cited by 49 publications

(22 citation statements)

References 26 publications

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“…This suggests that some dependence of u c might exist with the ion species and the energy range. A relation could also exist with very early reports on the dependence of the pattern properties with the target temperature for the case of Ar þ and Ne þ irradiations [17,86]. In these cases, it was necessary to reduce the temperature in order to pattern the surface with lighter ions, in contrast e.g.…”

Section: Medium-energy (10-200 Kev)mentioning

confidence: 72%

“…Obviously, without beam scanning the surface would be expected to reach higher temperatures than when the ion beam is scanned. Moreover, the early results by Carter et al [17,86] on the role of the target temperature further indicate the importance of this variable. Here, it was found that reducing the target temperature below room temperature promoted the initiation and evolution of roughening (patterning) at lower fluences.…”

Section: Medium-energy (10-200 Kev)mentioning

confidence: 90%

“…In those early years, IBS-induced patterns were considered rather as a problem in the field of depth profiling analysis, due to the change of the sputtering yield with the local incidence angle [17,18]. Nevertheless, as mentioned above, their characteristics and potentialities still led Taniguchi in 1974 to propose erosion of solid targets through IBS as a promising nanostructuring technique [1].…”

Section: Historical Overviewmentioning

confidence: 99%

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Self-organized nanopatterning of silicon surfaces by ion beam sputtering

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Section: Medium-energy (10-200 Kev)mentioning

confidence: 72%

Section: Medium-energy (10-200 Kev)mentioning

confidence: 90%

Section: Historical Overviewmentioning

confidence: 99%

See 1 more Smart Citation

Self-organized nanopatterning of silicon surfaces by ion beam sputtering

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Vázquez

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et al. 2014

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“…С точки зрения аэродинамики интересна поверхность с периодической структурой гребней, которая образуется при распылении поверхности наклонным пучком ионов в определенном интервале температу-ры, зависящем от вида и энергии иона [23]. Поскольку в большинстве случаев необходимый интервал -это температуры ниже комнатной, то для получения такой структуры необходимо охлаждение мишени.…”

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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“…[19][20][21][22][23] Ripple formation during oblique angle irradiation on technologically important Si surfaces has begun in large magnitude by the studies of Carter and Vishnyakov. 24,25 Furthermore, nanodot formation study by Gago et al 26 on Si surfaces under normal incidence has generated a new view on pattern formation at the nano scale. Ozaydin et al 27 observed that the surface remains flat at normal incidence ion bombardment under ultra-high vaccum condition which was contradicting the observation of Gago et al 26 These observations strongly suggest that the nanopattern observed in earlier experimental reports on Si surface was due to the unintentionally deposited impurities.…”

mentioning

confidence: 99%

Investigation of the mechanism of impurity assisted nanoripple formation on Si induced by low energy ion beam erosion

Vayalil

Gupta

Roth³

et al. 2015

Journal of Applied Physics

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Articles you may be interested inA detailed mechanism of the nanoripple pattern formation on Si substrates generated by the simultaneous incorporation of pure Fe impurities at low energy (1 keV) ion beam erosion has been studied. To understand and clarify the mechanism of the pattern formation, a comparative analysis of the samples prepared for various ion fluence values using two complimentary methods for nanostructure analysis, atomic force microscopy, and grazing incidence small angle x-ray scattering has been done. We observed that phase separation of the metal silicide formed during the erosion does not precede the ripple formation. It rather concurrently develops along with the ripple structure. Our work is able to differentiate among various models existing in the literature and provides an insight into the mechanism of pattern formation under ion beam erosion with impurity incorporation. V C 2015 AIP Publishing LLC.[http://dx

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The effects of ion species and target temperature on topography development on ion bombarded Si

Cited by 49 publications

References 26 publications

Self-organized nanopatterning of silicon surfaces by ion beam sputtering

Self-organized nanopatterning of silicon surfaces by ion beam sputtering

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

Investigation of the mechanism of impurity assisted nanoripple formation on Si induced by low energy ion beam erosion

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