Interfacial Structure and Dynamics of Siloxane Systems: PDMS−Vapor and PDMS−Water
Citations Over TimeTop 10% of 2009 papers
Abstract
Using a fully atomistic force field for polydimethylsiloxane developed by Smith et al. [J. Phys. Chem. B 2004, 108, 20340], we study the interfacial properties of polydimethylsiloxane (PDMS) as well as its interactions with water. We determine the surface tension of methyl- and hydroxyl-terminated PDMS chains with lengths between 20 and 100 repeat units and find good agreement between simulation results and experimental observations. The width of the polymer liquid−vapor interface is shown to depend on both molecular weight and temperature. The surface tension and contact angle are determined for the PDMS−water binary system using several different geometries and calculation methods. At 300 K, the surface tension of roughly 41 mN/m and contact angle of ≈108° for chains with 100 repeat units are in excellent agreement with experimental data. The width of the interface in both the PDMS and water layers increases with temperature, although the computed widths are significantly smaller than the liquid−vapor widths of the individual liquids. The diffusion constant measured for low concentrations of water molecules permeating through PDMS shows a wide degree of variation as a result of “caging” effects caused by local density inhomogeneities. At larger concentrations, aggregation of the water molecules leads to phase separation. Finally, the degrees of alignment of the methyl groups and siloxane backbones at the interface are found to decrease with temperature but are augmented in the presence of an interface with water.
Related Papers
- → Perforated membrane method for fabricating three-dimensional polydimethylsiloxane microfluidic devices(2008)52 cited
- → Heat‐ and water‐proof quantum dot/siloxane composite film: Effect of quantum dot–siloxane linkage(2017)7 cited
- A novel method for fabricating polydimethylsiloxane microfluidic chip master molds(2009)
- 음식물류폐기물폐수의 혐기성 소화에서 바이오가스의 실록산 농도 특성(2011)
- 매립지 특성이 매립가스 내 siloxane 발생에 미치는 영향(2011)