Molecular Dynamics Simulations of Alkylsilane Monolayers on Silica Nanoasperities: Impact of Surface Curvature on Monolayer Structure and Pathways for Energy Dissipation in Tribological Contacts

Ewers, Bradley W.; Batteas, James D.

doi:10.1021/jp303097v

Cited by 33 publications

(45 citation statements)

References 130 publications

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“…Table ) demonstrate the high quality of the OTS‐SAM: the electron density of the tail group of 0.359(9)Å −3 indicates a very dense layer of chains. Theoretically, for rigid and perfectly upright standing silanes, this corresponds to about four silane chains per nm 2 , which also agrees with the arrangement seen in molecular dynamics simulations . For the tail group layer, the effective density model gives a thickness of 20.7(1)Å, which is in agreement with the bare length of the OTS tail group .…”

Section: Characterizationsupporting

confidence: 83%

Self‐assembled silane monolayers: an efficient step‐by‐step recipe for high‐quality, low energy surfaces

Lessel

Bäumchen

Klos

et al. 2015

Surface & Interface Analysis

111

125

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Organosilane self-assembled monolayers (SAMs) are commonly used for modifying a wide range of substrates. Depending on the end group, highly hydrophobic or hydrophilic surfaces can be achieved. Silanization bases on the adsorption, self-assembly and covalent binding of silane molecules onto surfaces and results in a densely packed, SAM. Following wet chemical routines, the quality of the monolayer is often variable and, therefore, unsatisfactory. The process of self-assembly is not only affected by the chemicals involved and their purity but is also extremely sensitive to ambient parameters such as humidity or temperature and to contaminants. Here, a reliable and efficient wet-chemical recipe is presented for the preparation of ultra-smooth, highly ordered alkyl-terminated silane SAMs on Si wafers. The resulting surfaces are characterized by means of atomic force microscopy, X-ray reflectometry and contact angle measurements.

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Section: Characterizationsupporting

confidence: 83%

Self‐assembled silane monolayers: an efficient step‐by‐step recipe for high‐quality, low energy surfaces

Lessel

Bäumchen

Klos

et al. 2015

Surface & Interface Analysis

111

125

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show abstract

“…The lower friction pair was a square plate made from AISI 316L stainless steel with a size of 20 9 20 9 2 mm, the surface of which was polished to a roughness of Ra = 2.7 nm over the area of 1 lm 9 1 lm measured by the tapping mode AFM (Veeco). The roughness of the lower-friction pair was quite close to that of the stainless steel coating on quartz crystal sensor, minimizing the difference in adsorption behavior caused by roughness [44]. A zirconium dioxide (ZrO 2 ) ball (obtained from Sinomaceramics, Beijing, China) was used as the upper friction pair with a diameter of 6.35 mm and surface roughness of Ra = 20 nm.…”

Section: Tribology Testmentioning

confidence: 99%

Stick–Slip Friction of Stainless Steel in Sodium Dodecyl Sulfate Aqueous Solution in the Boundary Lubrication Regime

Zhang

Meng

2014

Tribol Lett

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The objective of this study is to correlate the mass and structure of the adsorbed sodium dodecyl sulfate (SDS) on stainless steel surface in aqueous solution with the boundary lubrication behavior, especially the stick-slip phenomenon of the ZrO 2 /stainless steel friction pair. Surface tension measurement, quartz crystal microbalance (QCM) technique and ball-on-flat friction test were performed in this study. The adsorption isotherm of SDS on stainless steel surface in SDS aqueous solution was measured by QCM, and four-stage adsorption behavior was found at the solid/liquid interface. As the SDS concentration increases, the mass of the adsorbed SDS molecules increases, while the structure of the adsorbed layer changes from monomers to hemimicelles. Tribological properties of ZrO 2 /stainless steel friction pair in SDS aqueous solution were verified with an UMT-3 tester. Boundary lubrication was emphasized as water-based lubrication easily fails in hydrodynamic lubrication due to its low viscosity. Stickslip phenomenon was observed in the boundary lubrication of the adsorbed SDS film under certain loading and sliding conditions. Both the static and kinetic friction coefficients were analyzed with respect to the SDS concentration and sliding velocity. The stick-slip phenomenon is related to both of the adsorbed mass and adsorption structure of the SDS boundary film.

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“…Neste sentido, a Figura 3 apresenta um exemplo de possível aplicação de NPs funcionalizadas. A funcionalização pode ocorrer pela adição de grupos químicos funcionais à superfície de uma NP, conferindo novas funções, características ou propriedades ao material, alterando a química da superfície (EWERS, 2012, RIGO, 2014, DE LARA, 2015, 2015a Condicional: se raio_átomo_candidado > referência, faça: j = j + 1;…”

Section: Nanopartículas Funcionalizadasunclassified

Considerações Sobre O Estudo De Estado Da Arte Do Desenvolvimento De Modelos De Propagação Ar-Terra Em Veículos Aéreos Não Tripulados

Lopes¹,

Barros²,

Cruz³

et al. 2020

Estudos Teórico-Metodológicos Nas Ciências Exatas

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Molecular Dynamics Simulations of Alkylsilane Monolayers on Silica Nanoasperities: Impact of Surface Curvature on Monolayer Structure and Pathways for Energy Dissipation in Tribological Contacts

Cited by 33 publications

References 130 publications

Self‐assembled silane monolayers: an efficient step‐by‐step recipe for high‐quality, low energy surfaces

Self‐assembled silane monolayers: an efficient step‐by‐step recipe for high‐quality, low energy surfaces

Stick–Slip Friction of Stainless Steel in Sodium Dodecyl Sulfate Aqueous Solution in the Boundary Lubrication Regime

Considerações Sobre O Estudo De Estado Da Arte Do Desenvolvimento De Modelos De Propagação Ar-Terra Em Veículos Aéreos Não Tripulados

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