Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors
Gu, Ji-Dong ; Yang, Shunjuan ; Welton, R. ; Eberiel, D. ; McCarthy, S. P. ; Gross, R. A.
Springer
Published 1994
Springer
Published 1994
| ISSN: |
1572-8900
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|---|---|
| Keywords: |
Cellulose acetate ; polymer degradation ; polymer biodegradation ; plastic film weight loss ; biodegradable polymers ; municipal solid waste ; compost simulation ; biodegradation testing ; moisture content ; synthetic compost mixes
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| Source: |
Springer Online Journal Archives 1860-2000
|
| Topics: |
Chemistry and Pharmacology
Energy, Environment Protection, Nuclear Power Engineering
Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics
|
| Notes: |
Abstract Previous research in our laboratory reported a convenient laboratory-scale composting test method to study the weight loss of polymer films in aerobic thermophilic (53°C) reactors maintained at a 60% moisture content. The laboratory-scale compost reactors contained the following synthetic compost mixture (percentage on dry-weight basis): tree leaves (45.0), shredded paper (16.5), food (6.7), meat (5.8), cow manure (17.5), sawdust (1.9), aluminum and steel shavings (2.4), glass beads (1.3), urea (1.9), and a compost seed (1.0) which is designated Mix-1 in this work. To simplify the laboratory-scale compost weight loss test method and better understand how compost mixture compositions and environmental parameters affect the rate of plastic degradation, a systematic variation of the synthetic mixture composition as well as the moisture content was carried out. Cellulose acetate (CA) with a degree of substitution (DS) value of 1.7 and cellophane films were chosen as test polymer substrates for this work. The extent of CA DS-1.7 and cellophane weight loss as a function of the exposure time remained unchanged when the metal and glass components of the mixture were excluded in Mix-2. Further study showed that large variations in the mixture composition such as the replacement of tree leaves, food, meat, and sawdust with steam-exploded wood and alfalfa (forming Mix-C) could be made with little or no change in the time dependence of CA DS-1.7 film weight loss. In contrast, substituting tree leaves, food, meat, cow manure, and sawdust with steam-exploded wood in combination with either Rabbit Choice (Mix-D) or starch and urea (Mix-E) resulted in a significant time increase (from 7 to 12 days) for the complete disappearance of CA DS-1.7 films. Interestingly, in this work no direct correlation was observed between the C/N ratio (which ranged from 13.9 to 61.4) and the CA DS-1.7 film weight loss. Decreasing moisture contents of the compost Mix-2 from 60 and 50 and 40% resulted in dramatic changes in polymer degradation such that CA DS-1.7 showed an increase in the time period for a complete disappearance of polymer films from 6 to 16 and 30 days, respectively.
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| Type of Medium: |
Electronic Resource
|
| URL: |
| _version_ | 1798296407599218690 |
|---|---|
| autor | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. |
| autorsonst | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. |
| book_url | http://dx.doi.org/10.1007/BF02074781 |
| datenlieferant | nat_lic_papers |
| hauptsatz | hsatz_simple |
| identnr | NLM197788491 |
| iqvoc_descriptor_keyword | iqvoc_00000786:simulation |
| issn | 1572-8900 |
| journal_name | Journal of polymers and the environment |
| materialart | 1 |
| notes | Abstract Previous research in our laboratory reported a convenient laboratory-scale composting test method to study the weight loss of polymer films in aerobic thermophilic (53°C) reactors maintained at a 60% moisture content. The laboratory-scale compost reactors contained the following synthetic compost mixture (percentage on dry-weight basis): tree leaves (45.0), shredded paper (16.5), food (6.7), meat (5.8), cow manure (17.5), sawdust (1.9), aluminum and steel shavings (2.4), glass beads (1.3), urea (1.9), and a compost seed (1.0) which is designated Mix-1 in this work. To simplify the laboratory-scale compost weight loss test method and better understand how compost mixture compositions and environmental parameters affect the rate of plastic degradation, a systematic variation of the synthetic mixture composition as well as the moisture content was carried out. Cellulose acetate (CA) with a degree of substitution (DS) value of 1.7 and cellophane films were chosen as test polymer substrates for this work. The extent of CA DS-1.7 and cellophane weight loss as a function of the exposure time remained unchanged when the metal and glass components of the mixture were excluded in Mix-2. Further study showed that large variations in the mixture composition such as the replacement of tree leaves, food, meat, and sawdust with steam-exploded wood and alfalfa (forming Mix-C) could be made with little or no change in the time dependence of CA DS-1.7 film weight loss. In contrast, substituting tree leaves, food, meat, cow manure, and sawdust with steam-exploded wood in combination with either Rabbit Choice (Mix-D) or starch and urea (Mix-E) resulted in a significant time increase (from 7 to 12 days) for the complete disappearance of CA DS-1.7 films. Interestingly, in this work no direct correlation was observed between the C/N ratio (which ranged from 13.9 to 61.4) and the CA DS-1.7 film weight loss. Decreasing moisture contents of the compost Mix-2 from 60 and 50 and 40% resulted in dramatic changes in polymer degradation such that CA DS-1.7 showed an increase in the time period for a complete disappearance of polymer films from 6 to 16 and 30 days, respectively. |
| package_name | Springer |
| publikationsjahr_anzeige | 1994 |
| publikationsjahr_facette | 1994 |
| publikationsjahr_intervall | 8009:1990-1994 |
| publikationsjahr_sort | 1994 |
| publisher | Springer |
| reference | 2 (1994), S. 129-135 |
| schlagwort | Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes |
| search_space | articles |
| shingle_author_1 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. |
| shingle_author_2 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. |
| shingle_author_3 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. |
| shingle_author_4 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. |
| shingle_catch_all_1 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Abstract Previous research in our laboratory reported a convenient laboratory-scale composting test method to study the weight loss of polymer films in aerobic thermophilic (53°C) reactors maintained at a 60% moisture content. The laboratory-scale compost reactors contained the following synthetic compost mixture (percentage on dry-weight basis): tree leaves (45.0), shredded paper (16.5), food (6.7), meat (5.8), cow manure (17.5), sawdust (1.9), aluminum and steel shavings (2.4), glass beads (1.3), urea (1.9), and a compost seed (1.0) which is designated Mix-1 in this work. To simplify the laboratory-scale compost weight loss test method and better understand how compost mixture compositions and environmental parameters affect the rate of plastic degradation, a systematic variation of the synthetic mixture composition as well as the moisture content was carried out. Cellulose acetate (CA) with a degree of substitution (DS) value of 1.7 and cellophane films were chosen as test polymer substrates for this work. The extent of CA DS-1.7 and cellophane weight loss as a function of the exposure time remained unchanged when the metal and glass components of the mixture were excluded in Mix-2. Further study showed that large variations in the mixture composition such as the replacement of tree leaves, food, meat, and sawdust with steam-exploded wood and alfalfa (forming Mix-C) could be made with little or no change in the time dependence of CA DS-1.7 film weight loss. In contrast, substituting tree leaves, food, meat, cow manure, and sawdust with steam-exploded wood in combination with either Rabbit Choice (Mix-D) or starch and urea (Mix-E) resulted in a significant time increase (from 7 to 12 days) for the complete disappearance of CA DS-1.7 films. Interestingly, in this work no direct correlation was observed between the C/N ratio (which ranged from 13.9 to 61.4) and the CA DS-1.7 film weight loss. Decreasing moisture contents of the compost Mix-2 from 60 and 50 and 40% resulted in dramatic changes in polymer degradation such that CA DS-1.7 showed an increase in the time period for a complete disappearance of polymer films from 6 to 16 and 30 days, respectively. 1572-8900 15728900 Springer |
| shingle_catch_all_2 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Abstract Previous research in our laboratory reported a convenient laboratory-scale composting test method to study the weight loss of polymer films in aerobic thermophilic (53°C) reactors maintained at a 60% moisture content. The laboratory-scale compost reactors contained the following synthetic compost mixture (percentage on dry-weight basis): tree leaves (45.0), shredded paper (16.5), food (6.7), meat (5.8), cow manure (17.5), sawdust (1.9), aluminum and steel shavings (2.4), glass beads (1.3), urea (1.9), and a compost seed (1.0) which is designated Mix-1 in this work. To simplify the laboratory-scale compost weight loss test method and better understand how compost mixture compositions and environmental parameters affect the rate of plastic degradation, a systematic variation of the synthetic mixture composition as well as the moisture content was carried out. Cellulose acetate (CA) with a degree of substitution (DS) value of 1.7 and cellophane films were chosen as test polymer substrates for this work. The extent of CA DS-1.7 and cellophane weight loss as a function of the exposure time remained unchanged when the metal and glass components of the mixture were excluded in Mix-2. Further study showed that large variations in the mixture composition such as the replacement of tree leaves, food, meat, and sawdust with steam-exploded wood and alfalfa (forming Mix-C) could be made with little or no change in the time dependence of CA DS-1.7 film weight loss. In contrast, substituting tree leaves, food, meat, cow manure, and sawdust with steam-exploded wood in combination with either Rabbit Choice (Mix-D) or starch and urea (Mix-E) resulted in a significant time increase (from 7 to 12 days) for the complete disappearance of CA DS-1.7 films. Interestingly, in this work no direct correlation was observed between the C/N ratio (which ranged from 13.9 to 61.4) and the CA DS-1.7 film weight loss. Decreasing moisture contents of the compost Mix-2 from 60 and 50 and 40% resulted in dramatic changes in polymer degradation such that CA DS-1.7 showed an increase in the time period for a complete disappearance of polymer films from 6 to 16 and 30 days, respectively. 1572-8900 15728900 Springer |
| shingle_catch_all_3 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Abstract Previous research in our laboratory reported a convenient laboratory-scale composting test method to study the weight loss of polymer films in aerobic thermophilic (53°C) reactors maintained at a 60% moisture content. The laboratory-scale compost reactors contained the following synthetic compost mixture (percentage on dry-weight basis): tree leaves (45.0), shredded paper (16.5), food (6.7), meat (5.8), cow manure (17.5), sawdust (1.9), aluminum and steel shavings (2.4), glass beads (1.3), urea (1.9), and a compost seed (1.0) which is designated Mix-1 in this work. To simplify the laboratory-scale compost weight loss test method and better understand how compost mixture compositions and environmental parameters affect the rate of plastic degradation, a systematic variation of the synthetic mixture composition as well as the moisture content was carried out. Cellulose acetate (CA) with a degree of substitution (DS) value of 1.7 and cellophane films were chosen as test polymer substrates for this work. The extent of CA DS-1.7 and cellophane weight loss as a function of the exposure time remained unchanged when the metal and glass components of the mixture were excluded in Mix-2. Further study showed that large variations in the mixture composition such as the replacement of tree leaves, food, meat, and sawdust with steam-exploded wood and alfalfa (forming Mix-C) could be made with little or no change in the time dependence of CA DS-1.7 film weight loss. In contrast, substituting tree leaves, food, meat, cow manure, and sawdust with steam-exploded wood in combination with either Rabbit Choice (Mix-D) or starch and urea (Mix-E) resulted in a significant time increase (from 7 to 12 days) for the complete disappearance of CA DS-1.7 films. Interestingly, in this work no direct correlation was observed between the C/N ratio (which ranged from 13.9 to 61.4) and the CA DS-1.7 film weight loss. Decreasing moisture contents of the compost Mix-2 from 60 and 50 and 40% resulted in dramatic changes in polymer degradation such that CA DS-1.7 showed an increase in the time period for a complete disappearance of polymer films from 6 to 16 and 30 days, respectively. 1572-8900 15728900 Springer |
| shingle_catch_all_4 | Gu, Ji-Dong Yang, Shunjuan Welton, R. Eberiel, D. McCarthy, S. P. Gross, R. A. Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Cellulose acetate polymer degradation polymer biodegradation plastic film weight loss biodegradable polymers municipal solid waste compost simulation biodegradation testing moisture content synthetic compost mixes Abstract Previous research in our laboratory reported a convenient laboratory-scale composting test method to study the weight loss of polymer films in aerobic thermophilic (53°C) reactors maintained at a 60% moisture content. The laboratory-scale compost reactors contained the following synthetic compost mixture (percentage on dry-weight basis): tree leaves (45.0), shredded paper (16.5), food (6.7), meat (5.8), cow manure (17.5), sawdust (1.9), aluminum and steel shavings (2.4), glass beads (1.3), urea (1.9), and a compost seed (1.0) which is designated Mix-1 in this work. To simplify the laboratory-scale compost weight loss test method and better understand how compost mixture compositions and environmental parameters affect the rate of plastic degradation, a systematic variation of the synthetic mixture composition as well as the moisture content was carried out. Cellulose acetate (CA) with a degree of substitution (DS) value of 1.7 and cellophane films were chosen as test polymer substrates for this work. The extent of CA DS-1.7 and cellophane weight loss as a function of the exposure time remained unchanged when the metal and glass components of the mixture were excluded in Mix-2. Further study showed that large variations in the mixture composition such as the replacement of tree leaves, food, meat, and sawdust with steam-exploded wood and alfalfa (forming Mix-C) could be made with little or no change in the time dependence of CA DS-1.7 film weight loss. In contrast, substituting tree leaves, food, meat, cow manure, and sawdust with steam-exploded wood in combination with either Rabbit Choice (Mix-D) or starch and urea (Mix-E) resulted in a significant time increase (from 7 to 12 days) for the complete disappearance of CA DS-1.7 films. Interestingly, in this work no direct correlation was observed between the C/N ratio (which ranged from 13.9 to 61.4) and the CA DS-1.7 film weight loss. Decreasing moisture contents of the compost Mix-2 from 60 and 50 and 40% resulted in dramatic changes in polymer degradation such that CA DS-1.7 showed an increase in the time period for a complete disappearance of polymer films from 6 to 16 and 30 days, respectively. 1572-8900 15728900 Springer |
| shingle_title_1 | Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors |
| shingle_title_2 | Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors |
| shingle_title_3 | Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors |
| shingle_title_4 | Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors |
| sigel_instance_filter | dkfz geomar wilbert ipn albert fhp |
| source_archive | Springer Online Journal Archives 1860-2000 |
| timestamp | 2024-05-06T09:51:36.886Z |
| titel | Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors |
| titel_suche | Effect of environmental parameters on the degradability of polymer films in laboratory-scale composting reactors |
| topic | V ZP ZL |
| uid | nat_lic_papers_NLM197788491 |