Viscosity and Surface-Promoted Slippage of Thin Polymer Films Supported by a Solid Substrate

Chen, Fei; Peng, Dongdong; Lam, Chi Hang; Tsui, Ophelia Kwan Chui

doi:10.1021/acs.macromol.5b01002

Cited by 37 publications

(99 citation statements)

References 52 publications

(113 reference statements)

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“…These data for the thickness dependent viscosity can be modeled using a two layer model that includes a mobile surface layer . For low molecular weight polymers below the entanglement molecular weight, no‐slip boundary condition appears to be valid from the analysis, but for polymers above the entanglement molecular weight slip at the substrate boundary must be included in the model; the authors attributed the slip to the surface mobile layer . The decrease in the effective viscosity of PS when confined is consistent with expectations based on the measures of enhanced dynamics in thin PS films .…”

Section: Flow Properties Of Rubbery Polymers Under Confinementsupporting

confidence: 72%

Mechanical and viscoelastic properties of confined amorphous polymers

Vogt

2017

J Polym Sci B Polym Phys

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Confinement of polymers to nanoscale dimensions can dramatically impact their physical properties. Substantial efforts have focused on the glass transition temperature (T g ) of polymers confined to thin films, but their mechanical properties are less studied despite their technological importance. In this review, challenges with mechanical measurements of polymer thin films are discussed along with novel metrologies that provide insight into their mechanical properties. A comparison of experimental measurements, simulations and theory provide several general conclusions about the mechanical properties under confinement. Confinement impacts the elastic modulus, rubbery compliance and viscosity of polystyrene, the archetypal polymer for confinement, but the confinement effect appears to depend on the measurement technique. This effect may be due to the details of averaging of gradients in properties that are dependent on the measurement details. Routes to minimize confinement effects are addressed. Despite progress in the measurements of mechanical properties of polymer thin films, there remain unresolved questions about the impact of confinement, which we highlight at the end of this review. 1,2 These concerns persist for polymeric nanostructures, where mechanical properties are critical to feature stability. 3 The mechanical properties of many polymers are dependent on their processing history,

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Section: Flow Properties Of Rubbery Polymers Under Confinementsupporting

confidence: 72%

Mechanical and viscoelastic properties of confined amorphous polymers

Vogt

2017

J Polym Sci B Polym Phys

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“…In the past few decades, there have been many experiments measuring deviations from the no-slip boundary condition at microscopic length scales [1][2][3][4][5]. These measurements have stimulated the interest in hydrodynamic slip for both the fundamental understanding of the molecular mechanisms involved, as well as the impact of slip on technological applications [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20].…”

mentioning

confidence: 99%

Adsorption-induced slip inhibition for polymer melts on ideal substrates

et al. 2018

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Hydrodynamic slip, the motion of a liquid along a solid surface, represents a fundamental phenomenon in fluid dynamics that governs liquid transport at small scales. For polymeric liquids, de Gennes predicted that the Navier boundary condition together with polymer reptation implies extraordinarily large interfacial slip for entangled polymer melts on ideal surfaces; this Navier-de Gennes model was confirmed using dewetting experiments on ultra-smooth, low-energy substrates. Here, we use capillary leveling—surface tension driven flow of films with initially non-uniform thickness—of polymeric films on these same substrates. Measurement of the slip length from a robust one parameter fit to a lubrication model is achieved. We show that at the low shear rates involved in leveling experiments as compared to dewetting ones, the employed substrates can no longer be considered ideal. The data is instead consistent with a model that includes physical adsorption of polymer chains at the solid/liquid interface.

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“…However, the results from the experiments of Tsui [38][39][40] and Bodiguel 15 which show a significant reduction in the viscosity of thin films supported by a substrate with repulsive interaction, may suggest that the flexible long-chains are less entangled in the thin film, from the viewpoint of the tube theory (i.e. However, the results from the experiments of Tsui [38][39][40] and Bodiguel 15 which show a significant reduction in the viscosity of thin films supported by a substrate with repulsive interaction, may suggest that the flexible long-chains are less entangled in the thin film, from the viewpoint of the tube theory (i.e.…”

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confidence: 99%

Probing the rheological properties of supported thin polystyrene films by investigating the growth dynamics of wetting ridges

et al. 2016

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Despite its importance in the processing of nanomaterials, the rheological behavior of thin polymer films is poorly understood, partly due to the inherent measurement challenges. Herein, we have developed a facile method for investigating the rheological behavior of supported thin polymeric films by monitoring the growth of the "wetting ridge"-a microscopic protrusion on the film surface due to the capillary forces exerted by a drop of ionic liquid placed on the film surface. It was found that the growth dynamics of the wetting ridge and the behavior of polystyrene rheology are directly linked. Important rheological properties, such as the flow temperature (Tf), viscosity (η), and terminal relaxation time (τ0) of thin polystyrene films, can be derived by studying the development of the height of the wetting ridge with time and the sample temperature. Rheological studies using the proposed approach for supported thin polystyrene (PS) films with thickness down to 20 nm demonstrate that the PS thin film exhibits facilitated flow, with reduced viscosity and lowered viscous temperature and a shortened rubbery plateau, when SiOx-Si was used as the substrate. However, sluggish flow was observed for the PS film supported by hydrogen-passivated silicon substrates (H-Si). The differences in enthalpic interactions between PS and the substrates are the reason for this divergence in the whole-chain mobility and flow ability of thin PS films deposited on SiOx-Si and H-Si surfaces. These results indicate that this approach could be a reliable rheological probe for supported thin polymeric films with different thicknesses and various substrates.

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Viscosity and Surface-Promoted Slippage of Thin Polymer Films Supported by a Solid Substrate

Cited by 37 publications

References 52 publications

Mechanical and viscoelastic properties of confined amorphous polymers

Mechanical and viscoelastic properties of confined amorphous polymers

Adsorption-induced slip inhibition for polymer melts on ideal substrates

Probing the rheological properties of supported thin polystyrene films by investigating the growth dynamics of wetting ridges

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