Plasma‐Polymerization of HMDSO Using an Atmospheric Pressure Dielectric Barrier Discharge

Morent, Rino; Geyter, Nathalie De; Jacobs, Tinneke; Vlierberghe, Sandra Van; Dubruel, Peter; Leys, Christophe; Schacht, Etienne

doi:10.1002/ppap.200931101

Cited by 68 publications

(61 citation statements)

References 21 publications

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“…Many studies showed that deposition time can lead to an increase in the thickness of the coating [77,78,89]. The results of 25 minute deposition time (contact angle and contact angle hysteresis) were satisfactory, however.…”

Section: ïV-3-optimization Of Plasma Process Parametersmentioning

confidence: 92%

“…By increasing the monomer flow rate, the concentration of methyl groups can also increase. However, it may lead to coating delaminate [31,89].…”

Section: Ii-4-4-influence Of Monomer Flow On Wettabilitymentioning

confidence: 99%

“…27 Figure 11.13: Molecular structure of a) Acrylic acid (unsaturated), b) Perfluorohexane (linear saturated) and c) Octafluorotoluene (cyclic unsaturated) [65] .28 Figure 11.14: R.F. Variation of contact angles for the different plasma precursors deposited a) FAS-3, b) FAS-13, and c) FAS-17 [66] 29 Figure 11.15: AFM Images of a) untreated silicon wafer, b) PP-HMDSO coating deposited at 30 sec deposition and c) PP-HMDSO film at 5 min deposition [77]..... 32 Figure 11.16: Advancing and receding contact angle of PP-HMDSO film at different deposition times on a) wafer silicon b) polyethylene [77] 33 Figure 11.17: Contact angle of PP-Hexafluoropropylene coating on poly(vinyl chloride) tube as a function of deposition time [64] 34 Figure 11.18: FT-IR spectra of PP-HMDSO films deposited with different monomer concentrations (discharge power 9.5 W, film thickness 700 nm) [89] 35 Figure 11.19: SEM images of the coatings at a) 1, b) 3, c) 5, d) 8, e) 11, and f) 18 cm from the gas inlet [73] .....36 Figure 11.20: Static, advancing, and receding contact angle vs. axial position of samples from the gas inlet [73] • ..37 [95]. ...43 Figure 11.26: X-ray photoelectron spectroscopy F/C ratio of plasma-polymerized fluorocarbon coatings deposited on stainless steel as a function of immersion time in distilled water [105] 44 Figure 11.27: Atomic force microscopy images 2^2 (im 2 of plasma-polymerized thin coating after: (a) 0 week, (b) 1 week, (c) 2 weeks, (d) 3 weeks and (e) 4 weeks of ageing in D.I.…”

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confidence: 99%

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Development of nano-structured icephobic surfaces based on plasma polymerization /

Mobarakeh¹

2014

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Accumulated ice on exposed surfaces leads to operational difficulties and extensive maintenance for power transmission lines, antennas, aircraft, ships, and ground transportation vehicles.In the present study, the low pressure plasma polymerized Hexamethyldisiloxane (PP-HMDSO) film is deposited on aluminum surfaces to create a superhydrophobic coating with icephobic properties. Prior to the deposition of this low surface energy coating, aluminum surfaces were anodized or immersed in boiling water to make micro/nano structured surfaces.Plasma parameters were optimized in order to find the best optimum conditions for having high static contact angle and low contact angle hysteresis. Hence, the Grey-based Taguchi method was used as one of the Design of Experiment (DOE) techniques. The stability of coatings was studied under accelerated aging conditions such as UV degradation, immersion in distilled water and different pH solutions, and several icing/deicing cycles. It was observed that the PP-HMDSO coatings are quite stable against UV exposure and immersion in distilled water. However, the icephobicity of the PP-HMDSO coating deposited on the anodized aluminum decreased after fifteen icing/de-icing cycles.The stability of the developed coating was improved against several icing/de-icing cycles by increasing the deposition time of plasma polymerized coating from 15 to 25 minutes. The results showed that increasing the deposition time of plasma polymerization leads to decrease of the ice adhesion strength of coatings on anodized aluminum while it has no significant effect on the PP-HMDSO coating deposited on a water-treated aluminum surface. Finally, the superhydrophobic PP-HMDSO coating also provides anti-corrosion protection for the aluminum substrate.

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Section: ïV-3-optimization Of Plasma Process Parametersmentioning

confidence: 92%

“…By increasing the monomer flow rate, the concentration of methyl groups can also increase. However, it may lead to coating delaminate [31,89].…”

Section: Ii-4-4-influence Of Monomer Flow On Wettabilitymentioning

confidence: 99%

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confidence: 99%

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Development of nano-structured icephobic surfaces based on plasma polymerization /

Mobarakeh¹

2014

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“…The common operational mode of atmospheric pressure DBD is filamentary (Ref 54,(57)(58)(59)(60)(61)(62)(63)(64)(65)(66)(67)71), resulting in strong spatial nonuniformity of plasma chemistry that can alter the quality of the films. On the contrary, glow DBD modes (Ref 53,55,56,(68)(69)(70)72), sometimes, referred to as low current atmospheric pressure Townsend-like discharge or high current atmospheric pressure glow-like discharge, are expected to give high quality films. This uniform mode of DBD is observed for a very restricted set of parameters such as gas mixture, dissipated power, operational frequency, etc.…”

Section: Low Power Sourcesmentioning

confidence: 99%

“…In Table 1, we list a set of works (Ref [53][54][55][56][57][58][59][60][61][62][63][64][65][66][67][68][69][70][71][72] showing the various possibilities investigated to deposit thin films by low power sources. The common operational mode of atmospheric pressure DBD is filamentary (Ref 54,(57)(58)(59)(60)(61)(62)(63)(64)(65)(66)(67)71), resulting in strong spatial nonuniformity of plasma chemistry that can alter the quality of the films.…”

Section: Low Power Sourcesmentioning

confidence: 99%