Polymer-brush lubrication in the limit of strong compression

Polymer-brush lubrication in the limit of strong compression

. By means of molecular dynamics simulations we demonstrate power laws for macroscopic transport properties of strongly compressed polymer-brush bilayers to stationary shear motion beyond the Newtonian response. The corresponding exponents are derived from a recently developed scaling theory, where...

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Veröffentlicht in:The European physical journal. E, Soft matter and biological physics Soft matter and biological physics, 2010-12, Vol.33 (4), p.307-311
Hauptverfasser: Spirin, L., Galuschko, A., Kreer, T., Johner, A., Baschnagel, J., Binder, K.
Format: Artikel
Sprache:eng
Schlagworte:
Applied sciences
Biological and Medical Physics
Biophysics
Complex Fluids and Microfluidics
Complex Systems
Compressive Strength
Exact sciences and technology
Lubricants - chemistry
Molecular Dynamics Simulation
Motion
Nanotechnology
Organic polymers
Physicochemistry of polymers
Physics
Physics and Astronomy
Polymer Sciences
Polymers - chemistry
Properties and characterization
Regular Article
Rheology and viscoelasticity
Shear Strength
Soft and Granular Matter
Stress, Mechanical
Surface Properties
Surfaces and Interfaces
Thin Films
Viscosity
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Beschreibung
Zusammenfassung:. By means of molecular dynamics simulations we demonstrate power laws for macroscopic transport properties of strongly compressed polymer-brush bilayers to stationary shear motion beyond the Newtonian response. The corresponding exponents are derived from a recently developed scaling theory, where the interpenetration between the brushes is taken as the relevant length scale. This allows to predict the dependence of the critical shear rate, which separates linear and non-linear behavior, on compression and molecular parameters of the bilayer. We present scaling plots for chain extension ( R , viscosity ( , and shear force ( F over a wide range of Weissenberg numbers, W . In agreement with our theory, the simulation reveals simple power laws, R ∼ W 0.53 , ∼ W -0.46 , and F ∼ W 0.54 , for the non-Newtonian regime.
ISSN:1292-8941
1292-895X
DOI:10.1140/epje/i2010-10674-3