Morphological Changes of Tungsten Surfaces by Low-Flux Helium Plasma Treatment and Helium Incorporation via Magnetron Sputtering

Iyyakkunnel, Santhosh; Marot, L.; Eren, Baran; Steiner, Roland; Moser, L.; Mathys, Daniel; Düggelin, Marcel; Chapon, Patrick; Meyer, Ernst

doi:10.1021/am502370t

Cited by 38 publications

(23 citation statements)

References 40 publications

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“…For each step a new fresh 20 nm tungsten film was deposited on silicon wafer by means of pulsed-DC magnetron sputtering of a 99.95% pure W target (details about the deposition parameters can be found in ref. 40).…”

Section: Surface Study In a Conventional Stainless Steel Vacuum Chambermentioning

confidence: 99%

Plasma-assisted catalytic formation of ammonia in N₂–H₂plasma on a tungsten surface

Yaala

Saeedi

Scherrer

et al. 2019

Phys. Chem. Chem. Phys.

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Section: Surface Study In a Conventional Stainless Steel Vacuum Chambermentioning

confidence: 99%

Plasma-assisted catalytic formation of ammonia in N₂–H₂plasma on a tungsten surface

Yaala

Saeedi

Scherrer

et al. 2019

Phys. Chem. Chem. Phys.

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“… 4 5 6 7 More recently, significant surface modifications were observed on tungsten under low-energy He ion irradiation, with ion energies below the threshold for damage creation, and investigated as a function of surface temperature, ion flux and exposure time. 8 9 10 11 These studies revealed the formation of a fine nanostructure exhibiting a high porosity of up to 90% and high light absorption. 12 13 14 The size of those nanostructures and thickness of the nanostructured layer could be controlled by surface temperature and plasma exposure time, respectively.…”

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confidence: 91%

Surface Modifications Induced by High Fluxes of Low Energy Helium Ions

Tanyeli

Marot

Mathys

et al. 2015

Sci Rep

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Several metal surfaces, such as titanium, aluminum and copper, were exposed to high fluxes (in the range of 1023 m−2s−1) of low energy (<100 eV) Helium (He) ions. The surfaces were analyzed by scanning electron microscopy and to get a better understanding on morphology changes both top view and cross sectional images were taken. Different surface modifications, such as voids and nano pillars, are observed on these metals. The differences and similarities in the development of surface morphologies are discussed in terms of the material properties and compared with the results of similar experimental studies. The results show that He ions induced void growth and physical sputtering play a significant role in surface modification using high fluxes of low energy He ions.

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“…However, other potential applications have been demonstrated such as annihilation of dislocations in GaN [12], reducing the threading dislocation density via the enhancement of the strain relaxation of SiGe/Si heterostructures [13], * marie-laure.david@univ-poitiers.fr the proximity gettering of metallic impurities [14], or the fabrication of ultrathin buried oxide layers in silicon [15]. Finally, low-energy helium plasma treatments have recently received considerable interest for nanostructuration of surfaces with applications in domains of energy conversion and storage devices, by both bottom-up [16] or top-down approaches [17,18]. In particular, nanopores in amorphous silicon coatings produced using such methods have been revealed to contain a high helium density [19].…”

Section: Introductionmentioning

confidence: 99%

Evolution of the properties of helium nanobubbles during in situ annealing probed by spectrum imaging in the transmission electron microscope

et al. 2018

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The evolution of nanometric helium bubbles in silicon has been investigated using spatially resolved electron energy-loss spectroscopy during in situ annealing in the transmission electron microscope. This approach allows the simultaneous determination of both the morphology and the helium density in the bubbles at each step of the annealing. Structural modification and helium emission from bubbles of various diameters in the range 7.5 to 20 nm and various aspect ratios of 1.1 to 1.9 have been studied. We clearly show that helium emission takes place at temperatures where bubble migration had hardly started. At higher temperatures, the migration (and coalescence) of voids is clearly revealed. For helium density lower than 150 He nm −3 , the Cerofolini's model taking into account the thermodynamical properties of an ultradense fluid reproduces well the helium emission from the bubbles, leading to an activation energy of 1.8 eV. When bubbles exhibit a higher initial helium density, the Cerofolini's model fails to reproduce the helium emission kinetics. We ascribe this to the fact that helium may be in the solid phase and we propose a tentative model to take into account the properties of the solid.

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Morphological Changes of Tungsten Surfaces by Low-Flux Helium Plasma Treatment and Helium Incorporation via Magnetron Sputtering

Cited by 38 publications

References 40 publications

Plasma-assisted catalytic formation of ammonia in N₂–H₂plasma on a tungsten surface

Plasma-assisted catalytic formation of ammonia in N₂–H₂plasma on a tungsten surface

Surface Modifications Induced by High Fluxes of Low Energy Helium Ions

Evolution of the properties of helium nanobubbles during in situ annealing probed by spectrum imaging in the transmission electron microscope

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Morphological Changes of Tungsten Surfaces by Low-Flux Helium Plasma Treatment and Helium Incorporation via Magnetron Sputtering

Cited by 38 publications

References 40 publications

Plasma-assisted catalytic formation of ammonia in N2–H2plasma on a tungsten surface

Plasma-assisted catalytic formation of ammonia in N2–H2plasma on a tungsten surface

Surface Modifications Induced by High Fluxes of Low Energy Helium Ions

Evolution of the properties of helium nanobubbles during in situ annealing probed by spectrum imaging in the transmission electron microscope

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Plasma-assisted catalytic formation of ammonia in N₂–H₂plasma on a tungsten surface

Plasma-assisted catalytic formation of ammonia in N₂–H₂plasma on a tungsten surface