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Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging

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Bibliographische Detailangaben
Zeitschriftentitel: Key Engineering Materials
Personen und Körperschaften: Maalihan, Reymark D., Pajarito, Bryan B.
In: Key Engineering Materials, 705, 2016, S. 72-76
Format: E-Article
Sprache: Unbestimmt
veröffentlicht:
Trans Tech Publications, Ltd.
Schlagwörter:
Mechanical Engineering
Mechanics of Materials
General Materials Science
author_facet Maalihan, Reymark D.
Pajarito, Bryan B.
Maalihan, Reymark D.
Pajarito, Bryan B.
author Maalihan, Reymark D.
Pajarito, Bryan B.
spellingShingle Maalihan, Reymark D.
Pajarito, Bryan B.
Key Engineering Materials
Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
Mechanical Engineering
Mechanics of Materials
General Materials Science
author_sort maalihan, reymark d.
spelling Maalihan, Reymark D. Pajarito, Bryan B. 1662-9795 Trans Tech Publications, Ltd. Mechanical Engineering Mechanics of Materials General Materials Science http://dx.doi.org/10.4028/www.scientific.net/kem.705.72 <jats:p>Polyethylene (PE) films with pro-oxidants are commonly used in agricultural and packaging industries due to their inherent biodegradability when initially expose to heat and/or light in the presence of oxygen. The degradation of films is characterized by formation of oxidation products, weight changes and loss of mechanical properties. This study investigated the relationship between tensile modulus and oxygen uptake of low-density PE films with pro-oxidants under thermal treatment at 50 and 70 °C. Blown-type films of varying colorants, thickness and pro-oxidant loading were formulated according to Taguchi design of experiments. Tensile modulus and oxygen uptake of thermally aged films were obtained from force-stroke curves and gravimetric tests, respectively. Results revealed that two out of nine formulated films showed tensile modulus to be significantly increasing with oxygen uptake at 50 °C. Correlation was more evident at 70 °C where seven out of nine formulations followed the same trend. The improvement in tensile modulus with oxygen uptake indicates increase in crystallinity of films during thermal aging. Increase in hydroxyl index of films with exposure time confirmed their degradation during heat aging. Consequently, concentration of carboxylic acids as major thermo-oxidation products was found higher at 70 °C of aging.</jats:p> Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging Key Engineering Materials
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series Key Engineering Materials
source_id 49
title Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_unstemmed Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_full Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_fullStr Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_full_unstemmed Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_short Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_sort relationship between tensile modulus and oxygen uptake of pro-oxidant loaded low-density polyethylene films during heat aging
topic Mechanical Engineering
Mechanics of Materials
General Materials Science
url http://dx.doi.org/10.4028/www.scientific.net/kem.705.72
publishDate 2016
physical 72-76
description <jats:p>Polyethylene (PE) films with pro-oxidants are commonly used in agricultural and packaging industries due to their inherent biodegradability when initially expose to heat and/or light in the presence of oxygen. The degradation of films is characterized by formation of oxidation products, weight changes and loss of mechanical properties. This study investigated the relationship between tensile modulus and oxygen uptake of low-density PE films with pro-oxidants under thermal treatment at 50 and 70 °C. Blown-type films of varying colorants, thickness and pro-oxidant loading were formulated according to Taguchi design of experiments. Tensile modulus and oxygen uptake of thermally aged films were obtained from force-stroke curves and gravimetric tests, respectively. Results revealed that two out of nine formulated films showed tensile modulus to be significantly increasing with oxygen uptake at 50 °C. Correlation was more evident at 70 °C where seven out of nine formulations followed the same trend. The improvement in tensile modulus with oxygen uptake indicates increase in crystallinity of films during thermal aging. Increase in hydroxyl index of films with exposure time confirmed their degradation during heat aging. Consequently, concentration of carboxylic acids as major thermo-oxidation products was found higher at 70 °C of aging.</jats:p>
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author Maalihan, Reymark D., Pajarito, Bryan B.
author_facet Maalihan, Reymark D., Pajarito, Bryan B., Maalihan, Reymark D., Pajarito, Bryan B.
author_sort maalihan, reymark d.
container_start_page 72
container_title Key Engineering Materials
container_volume 705
description <jats:p>Polyethylene (PE) films with pro-oxidants are commonly used in agricultural and packaging industries due to their inherent biodegradability when initially expose to heat and/or light in the presence of oxygen. The degradation of films is characterized by formation of oxidation products, weight changes and loss of mechanical properties. This study investigated the relationship between tensile modulus and oxygen uptake of low-density PE films with pro-oxidants under thermal treatment at 50 and 70 °C. Blown-type films of varying colorants, thickness and pro-oxidant loading were formulated according to Taguchi design of experiments. Tensile modulus and oxygen uptake of thermally aged films were obtained from force-stroke curves and gravimetric tests, respectively. Results revealed that two out of nine formulated films showed tensile modulus to be significantly increasing with oxygen uptake at 50 °C. Correlation was more evident at 70 °C where seven out of nine formulations followed the same trend. The improvement in tensile modulus with oxygen uptake indicates increase in crystallinity of films during thermal aging. Increase in hydroxyl index of films with exposure time confirmed their degradation during heat aging. Consequently, concentration of carboxylic acids as major thermo-oxidation products was found higher at 70 °C of aging.</jats:p>
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physical 72-76
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publisher Trans Tech Publications, Ltd.
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series Key Engineering Materials
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spelling Maalihan, Reymark D. Pajarito, Bryan B. 1662-9795 Trans Tech Publications, Ltd. Mechanical Engineering Mechanics of Materials General Materials Science http://dx.doi.org/10.4028/www.scientific.net/kem.705.72 <jats:p>Polyethylene (PE) films with pro-oxidants are commonly used in agricultural and packaging industries due to their inherent biodegradability when initially expose to heat and/or light in the presence of oxygen. The degradation of films is characterized by formation of oxidation products, weight changes and loss of mechanical properties. This study investigated the relationship between tensile modulus and oxygen uptake of low-density PE films with pro-oxidants under thermal treatment at 50 and 70 °C. Blown-type films of varying colorants, thickness and pro-oxidant loading were formulated according to Taguchi design of experiments. Tensile modulus and oxygen uptake of thermally aged films were obtained from force-stroke curves and gravimetric tests, respectively. Results revealed that two out of nine formulated films showed tensile modulus to be significantly increasing with oxygen uptake at 50 °C. Correlation was more evident at 70 °C where seven out of nine formulations followed the same trend. The improvement in tensile modulus with oxygen uptake indicates increase in crystallinity of films during thermal aging. Increase in hydroxyl index of films with exposure time confirmed their degradation during heat aging. Consequently, concentration of carboxylic acids as major thermo-oxidation products was found higher at 70 °C of aging.</jats:p> Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging Key Engineering Materials
spellingShingle Maalihan, Reymark D., Pajarito, Bryan B., Key Engineering Materials, Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging, Mechanical Engineering, Mechanics of Materials, General Materials Science
title Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_full Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_fullStr Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_full_unstemmed Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_short Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
title_sort relationship between tensile modulus and oxygen uptake of pro-oxidant loaded low-density polyethylene films during heat aging
title_unstemmed Relationship between Tensile Modulus and Oxygen Uptake of Pro-Oxidant Loaded Low-Density Polyethylene Films during Heat Aging
topic Mechanical Engineering, Mechanics of Materials, General Materials Science
url http://dx.doi.org/10.4028/www.scientific.net/kem.705.72