Relating strain hardening moduli in high density polyethylene copolymers to anisotropic molecular deformation using infrared spectroscopic imaging

Relating strain hardening moduli in high density polyethylene copolymers to anisotropic molecular deformation using infrared spectroscopic imaging

Understanding and establishing the relationship between the microstructure of high density polyethylene (HDPE) resins and their mechanical behavior is critical in designing new products and catalysts to produce these polymers. Recent advancement in the mid-infrared (IR) spectroscopic imaging techniq...

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Bibliographic Details
Published in:Polymer (Guilford) Vol. 172; pp. 398 - 403
Main Authors: Mukherjee, Prabuddha, Ghosh, Ayanjeet, Lamborn, Mark J., Monwar, Masud M., Fodor, Jeff S., DesLauriers, Paul J., Bhargava, Rohit
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 20-05-2019
Elsevier BV
Subjects:
Algorithms
Anisotropy
Catalysts
Chain entanglement
Cold drawing
Cold treatment
Deformation
Finite element method
High density polyethylenes
Imaging techniques
Infrared imaging
Infrared spectroscopy
Lamella
Mathematical models
Mechanical properties
Mid-infrared (IR) spectroscopy
Parameters
Polyethylene
Polymers
Resins
Strain hardening
Vibrational anisotropy
Polyethylene
Vibrational anisotropy
Mid-infrared (IR) spectroscopy
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Summary:Understanding and establishing the relationship between the microstructure of high density polyethylene (HDPE) resins and their mechanical behavior is critical in designing new products and catalysts to produce these polymers. Recent advancement in the mid-infrared (IR) spectroscopic imaging techniques combined with intuitive mathematical modelling can provide a powerful tool in solving this industry-wide long-standing challenge. In this work, IR spectral anisotropy methods coupled with the Crystal Tie Mesh (CTM) model were used to examine the effects of various resin architectures (monomodal and bimodal) on the bulk strain hardening moduli in cold drawn HDPE samples. Using a polarized laser for IR imaging, the related stress strain profiles of local strain gradients (100% sample strain) were modelled using a modified Eyring algorithm. A clear correlating trend was found between a resulting structural parameter in this algorithm (β) and the bulk strain hardening moduli for all samples studied. Results show that the more stable the molecular network (e.g., the lamella segments connected via bridging entanglements and tie molecules), the less strain is observed (i.e. higher β values) when a load is applied. The observed structural effects on the β parameter are consistent with previous results obtained using the CTM model that views the system to be a type of cross linked network formed by multiple bridging and entangled tie chains through common crystalline lamella. [Display omitted] •Vibrational Anisotropy can predict the bulk strain hardening moduli of tensile polyolefin samples.•We established structure parameter (b) using Eyring's model to identify the reason behind different strain hardening moduli.•Using a previously established crystal tie mesh model, we correlate the structure of these polyolefins with their strength.
ISSN:0032-3861
1873-2291
DOI:10.1016/j.polymer.2019.04.012