Effects of nanoscale thickness and elastic nonlinearity on measured mechanical properties of polymeric films

Effects of nanoscale thickness and elastic nonlinearity on measured mechanical properties of polymeric films

Scanning probe microscope-enabled nanoindentation is increasingly reported as a means to assess the mechanical properties of nanoscale, compliant material volumes such as polymeric films and bio-membranes. It has been demonstrated experimentally that the Hertzian contact model developed for linear e...

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Bibliographic Details
Published in:Thin solid films Vol. 513; no. 1; pp. 235 - 242
Main Authors: Oommen, B., Van Vliet, K.J.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 14-08-2006
Elsevier Science
Subjects:
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Condensed matter: structure, mechanical and thermal properties
Elasticity, elastic constants
Electronic structure and electrical properties of surfaces, interfaces, thin films and low-dimensional structures
Exact sciences and technology
Finite element analysis
Hyperelasticity
Mechanical and acoustical properties of condensed matter
Mechanical properties of solids
Nanoindentation
Physics
Polymers
Scanning probe microscopy
Tribology and hardness
Finite element analysis
Scanning probe microscopy
Polymers
Nanoindentation
Hyperelasticity
Elastic modulus
Membranes
Deformation
Digital simulation
Theoretical study
Mechanical properties
Ceramics
Nanostructures
Thin films
Thickness
Finite element method
Polyelectrolyte
Stress distribution
Size effect
Stiffness
Non linear effect
Organic compounds
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Description
Summary:Scanning probe microscope-enabled nanoindentation is increasingly reported as a means to assess the mechanical properties of nanoscale, compliant material volumes such as polymeric films and bio-membranes. It has been demonstrated experimentally that the Hertzian contact model developed for linear elastic materials of semi-infinite thickness fails to accurately predict the nominal elastic modulus E for polymeric thin films, consistent with limitations identified for comparably rigid metal and ceramic thin films. Here we employ computational simulations based on experimental parameters for compliant polyelectrolyte films, in order to separate limitations of such analysis due to the finite material thickness from those due to nonlinear constitutive relations approximating polymer deformation. We thus identify the range of strains, strain rates, and material thickness for which a modified Hertzian solution can accurately predict the elastic stiffness of polymeric films of nanoscale (< 100 nm) thickness from scanning probe microscope-enabled nanoindentation experiments.
Bibliography:ObjectType-Article-2
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ISSN:0040-6090
1879-2731
DOI:10.1016/j.tsf.2006.01.069