Shunsuke Koide scite author profile

Shunsuke Koide

4Publications

19Citation Statements Received

37Citation Statements Given

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Affiliations

Daido Metal (Japan), Komatsu (Japan), Nagoya University

Publications

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Effects of Using Alternative Extreme Pressure (EP) and Anti-Wear (AW) Additives with Oxy-Nitrided Samples

et al. 2018

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Oxy-nitriding is a widely used industrial process aiming to improve the tribological properties and performance of components. Previous studies have shown the effectiveness of the treatment with friction and wear performance, but very few have focussed on optimising this behaviour. The lubrication properties of several EP and AW additives were examined to investigate their effectiveness in improving the tribological properties of the layers formed after treatment. Previous studies showed the presence of an oxide layer on the sample could improve the effectiveness of the sulphurised olefin (SO) and tricresyl phosphate (TCP) additives. The friction and wear behaviour of oxy-nitrided samples were analysed using a tribometer and surface profiler. Scanning electron microscope, energy-dispersive X-ray spectroscopy and X-ray photoelectron spectroscopy were employed to identify the morphologies and chemical compositions of the treated surface before and after testing. No real effect on friction was observed when using the SO or TCP additives, mostly due to lack of interaction with the less reactive iron nitride layer and their roles as anti-wear additives. However, when the zinc dialkyldithiophosphatecontaining lubricant was used, a higher friction coefficient was observed. Greater improvements in anti-wear properties with the presence of additives in comparison with only using base oil were reported, with the TCP additive producing the lowest wear rates. The study effectively demonstrated that the additive package type used could impact the tribological and tribochemical properties of oxy-nitrided surfaces.

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Thermal reaction of polycrystalline SiC with XeF2

Watanabe¹,

Mori²,

Sakai³

et al. 2005

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Studies on the thermal reaction behavior of polycrystalline cubic silicon carbide (SiC) with effusive xenon difluoride (XeF2) have been carried out over the sample temperature (Ts) range from 300to900K using molecular beam quadrupole mass spectrometry combined with a time-of-flight technique and ex situ surface analyses, i.e., x-ray photoelectron spectroscopy (XPS) and scanning Auger microscopy (SAM). Above Ts=700K, the reaction product desorbed from the SiC surface was identified as SiF4. The flux intensity of SiF4 increases monotonically as a function of Ts above 700K. The flux intensity of XeF2 desorbed from the SiC surface decreases above Ts=700K, and at Ts=900K, approximately 10% of the incident XeF2 was found to be consumed by the thermal reaction. No ions at m∕e=31 (CF+), 50 (CF2+), and 69 (CF3+) to be ascribed to carbon fluoride species were detected under the present experimental conditions, and thus C atoms in SiC were found to remain as residue. From the XPS and SAM observations of the SiC samples exposed to XeF2 vapor at 1.8×10−4Torr, we find that fluorination of a native oxide layer formed on the SiC surface takes place at Ts=300K. At Ts=520K, the native oxide layer was partially removed from the surface, and the presence of a reaction layer composed of partially fluorinated C atoms was observed. As Ts is increased above 520K, the reaction layer becomes thicker. Above Ts=700K, a thick reaction layer mainly composed of C atoms is formed, while only the near-surface reaction layer is fluorinated. The fast desorption of SiF4 products reduces the Si concentration in the SiC surface and the residual C atoms having comprised the SiC lattice are left as the reaction layer.

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Surface Characterization of 3C-SiC Exposed to XeF₂

Watanabe

Mori

Sakai

et al. 2004

Jpn. J. Appl. Phys.

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The finite size of a fractal cluster of dimension D causes a reduction in the dimension of its projection to D* on any finite observation scale. A theoretical argument is presented which relates the apparent dimension D* to D and to the observation scale as a fraction of the outer fractal scale. The theory is tested for computer-generated fractal clusters. When applied to a sample of electron micrographs of diesel soot particles whose apparent dimension is 1.83 i-0.06, the theory gives 1.90 & 0.07 as the true fractal dimension of the soot.

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New EAF Dust Treatment Process for Co-Production of Metallic Zinc and Calcium-Ferrite

Koide

Mizuno

Yamaguchi

et al. 2020

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Shunsuke Koide

Effects of Using Alternative Extreme Pressure (EP) and Anti-Wear (AW) Additives with Oxy-Nitrided Samples

Thermal reaction of polycrystalline SiC with XeF2

Surface Characterization of 3C-SiC Exposed to XeF₂

New EAF Dust Treatment Process for Co-Production of Metallic Zinc and Calcium-Ferrite

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Shunsuke Koide

Effects of Using Alternative Extreme Pressure (EP) and Anti-Wear (AW) Additives with Oxy-Nitrided Samples

Thermal reaction of polycrystalline SiC with XeF2

Surface Characterization of 3C-SiC Exposed to XeF2

New EAF Dust Treatment Process for Co-Production of Metallic Zinc and Calcium-Ferrite

Contact Info

Product

Resources

About

Surface Characterization of 3C-SiC Exposed to XeF₂