Analysis of Stress Relaxation in Bulk and Porous Ultra-High Molecular Weight Polyethylene (UHMWPE).
Eugene S StatnikAlexey I SalimonYulia E GorshkovaNatallia S KaladzinskayaLudmila V MarkovaAlexander M KorsunskyPublished in: Polymers (2022)
The reported study was devoted to the investigation of viscoelastic behavior for solid and porous ultra-high molecular weight polyethylene (UHMWPE) under compression. The obtained experimental stress curves were interpreted using a two-term Prony series to represent the superposition of two coexisting activation processes corresponding to long molecular (~160 s) and short structural (~20 s) time scales, respectively, leading to good statistical correlation with the observations. In the case of porous polymer, the internal strain redistribution during relaxation was quantified using digital image correlation (DIC) analysis. The strongly inhomogeneous deformation of the porous polymer was found not to affect the relaxation times. To illustrate the possibility of generalizing the results to three dimensions, X-ray tomography was used to examine the porous structure relaxation at the macro- and micro-scale levels. DIC analysis revealed positive correlation between the applied force and relative density. The apparent stiffness variation for UHMWPE foams with mixed open and closed cells was described using a newly proposed three-term expression. Furthermore, in situ tensile loading and X-ray scattering study was applied for isotropic solid UHMWPE specimens to investigate the evolution of internal structure and orientation during drawing and stress relaxation in another loading mode.
Keyphrases
- single molecule
- high resolution
- metal organic framework
- tissue engineering
- highly efficient
- preterm infants
- deep learning
- magnetic resonance imaging
- machine learning
- stress induced
- magnetic resonance
- gestational age
- atomic force microscopy
- cell proliferation
- long non coding rna
- electron microscopy
- endoplasmic reticulum stress
- binding protein
- dual energy
- heat stress
- diffusion weighted imaging