Polymer Network Mobility and Environmental Stress Cracking Resistance of High Density Polyethylene

Zero shear viscosity and molecular weight between entanglements (M e ) are determined from dynamic oscillatory shear experiments. Lower M e value means higher number of entanglements in the system and is associated with increasing strain hardening stiffness. With the understanding that strain harden...

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Published in	Polymer-plastics technology and engineering Vol. 48; no. 12; pp. 1252 - 1261
Main Authors	Cheng, Joy J., Polak, Maria A., Penlidis, Alexander
Format	Journal Article
Language	English
Published	Philadelphia, PA Taylor & Francis Group 01.01.2009 Taylor & Francis
Subjects	Applied sciences Chain entanglements Environmental stress cracking resistance Exact sciences and technology High density High density polyethylene Mechanical properties Networks Organic polymers Physicochemistry of polymers Polyethylenes Polymer network mobility Properties and characterization Rheology and viscoelasticity Strain hardening Stress cracking High density polyethylene Non ionic surfactant High density ethylene polymer Mechanical properties Surfactant polymer Tensile property Experimental study Ethylene oxide polymer Shear viscosity Cyclic ether polymer Stress cracking Molecular mobility Olefin polymer Property structure relationship Polymer network mobility Chemical stress Molecular entanglement Chain entanglements Strain hardening Environmental stress cracking resistance Rheological properties
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ISSN	0360-2559 1525-6111
DOI	10.1080/03602550903159085

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Abstract	Zero shear viscosity and molecular weight between entanglements (M e ) are determined from dynamic oscillatory shear experiments. Lower M e value means higher number of entanglements in the system and is associated with increasing strain hardening stiffness. With the understanding that strain hardening is related to environmental stress cracking resistance (ESCR) of high density polyethylene (HDPE), M e is then related to the ESCR of several resins in this study. The inversely proportional relationship between M e and ESCR indicates that low network mobility due to an increasing number of chain entanglements increases the ESCR of HDPE.
AbstractList	Zero shear viscosity and molecular weight between entanglements (M e ) are determined from dynamic oscillatory shear experiments. Lower M e value means higher number of entanglements in the system and is associated with increasing strain hardening stiffness. With the understanding that strain hardening is related to environmental stress cracking resistance (ESCR) of high density polyethylene (HDPE), M e is then related to the ESCR of several resins in this study. The inversely proportional relationship between M e and ESCR indicates that low network mobility due to an increasing number of chain entanglements increases the ESCR of HDPE.
Author	Cheng, Joy J. Polak, Maria A. Penlidis, Alexander
Author_xml	– sequence: 1 givenname: Joy J. surname: Cheng fullname: Cheng, Joy J. organization: Institute for Polymer Research, Department of Chemical Engineering , University of Waterloo – sequence: 2 givenname: Maria A. surname: Polak fullname: Polak, Maria A. organization: Department of Civil and Environmental Engineering , University of Waterloo – sequence: 3 givenname: Alexander surname: Penlidis fullname: Penlidis, Alexander email: penlidis@cape.uwaterloo.ca organization: Institute for Polymer Research, Department of Chemical Engineering , University of Waterloo
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Keywords	High density polyethylene Non ionic surfactant High density ethylene polymer Mechanical properties Surfactant polymer Tensile property Experimental study Ethylene oxide polymer Shear viscosity Cyclic ether polymer Stress cracking Molecular mobility Olefin polymer Property structure relationship Polymer network mobility Chemical stress Molecular entanglement Chain entanglements Strain hardening Environmental stress cracking resistance Rheological properties
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SubjectTerms	Applied sciences Chain entanglements Environmental stress cracking resistance Exact sciences and technology High density High density polyethylene Mechanical properties Networks Organic polymers Physicochemistry of polymers Polyethylenes Polymer network mobility Properties and characterization Rheology and viscoelasticity Strain hardening Stress cracking
Title	Polymer Network Mobility and Environmental Stress Cracking Resistance of High Density Polyethylene
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