Evaluating the aerobic biodegradability of plastics in soil environments through GC and IR analysis of gaseous phase

The subject of this study was the verification of various alternatives for testing the biodegradability of polymers under soil conditions. The aim was to use gas chromatography to analyse the gaseous phase (CO 2 and O 2 content), a Micro-Oxymax respirometer (IR analysis of CO 2, analysis of O 2 by p...

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Published inPolymer testing Vol. 26; no. 6; pp. 729 - 741
Main Authors Dřímal, Pavel, Hoffmann, Jaromír, Družbík, Martin
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.09.2007
Elsevier
Subjects
Acidimetry
Applied sciences
Biodegradation
Exact sciences and technology
Gas chromatography
IR spectroscopy
Physical properties
Polymer industry, paints, wood
Properties and testing
Soil tests
Technology of polymers
Biodegradation
Gas chromatography
Acidimetry
Soil tests
IR spectroscopy
Biological properties
Microcrystalline material
Aerobiosis
Biodegradability
Ageing
Cellulose
Carbon dioxide
Ester polymer
Xanthan gum
Butyrate(hydroxy)polymer
Experimental study
Soils
Analysis method
Aliphatic polymer
Oside polymer
Fourier-transformed infrared spectrometry
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Abstract The subject of this study was the verification of various alternatives for testing the biodegradability of polymers under soil conditions. The aim was to use gas chromatography to analyse the gaseous phase (CO 2 and O 2 content), a Micro-Oxymax respirometer (IR analysis of CO 2, analysis of O 2 by paramagnetic analyser) to observe the biodegradation of polymeric substances in a soil environment in closed test flasks, and to compare measured results with a standard acidimetric procedure for determining CO 2. The experimental conditions of tests in soil were suggested as follows: test flasks of 1140 ml volume; dosage of soil inoculum: 30 g dry matter of soil and 30 g inert material (Perlite or other possessing comparable properties), soil moisture content approximately 50%, weight of test sample 150–300 mg with respect to the anticipated biodegradability. A frequency of analyses for CO 2 or O 2 content in the gaseous phase was selected so as to preserve aerobic conditions for tests (minimum 6 vol% O 2). Aeration (so-called “refresh”) was performed whenever the O 2 content in the gaseous phase of the closed flasks decreased. Under these conditions, the replacement of GC, IR and titration methods for determining CO 2 was verified in tests with a reference substrate, poly- β-hydroxybutyrate (PHB), and model samples (polysaccharide Xanthan, microcrystalline cellulose Avicel). Biodegradation was evaluated by CO 2 produced ( D CO 2 ) and O 2 consumed ( D O 2 ). Differences among values of D CO 2 were less than 5%. Differences between D CO 2 and D O 2 values (determined by GC analysis) were on a level not exceeding 10%. The selected test conditions for IR or GC determination of CO 2 and/or paramagnetic or GC determination of O 2 proved to be suitable for examining the biodegradability of substances in soils.
AbstractList The subject of this study was the verification of various alternatives for testing the biodegradability of polymers under soil conditions. The aim was to use gas chromatography to analyse the gaseous phase (CO sub(2) and O sub(2) content), a Micro-Oxymax respirometer (IR analysis of CO sub(2), analysis of O sub(2) by paramagnetic analyser) to observe the biodegradation of polymeric substances in a soil environment in closed test flasks, and to compare measured results with a standard acidimetric procedure for determining CO sub(2). The experimental conditions of tests in soil were suggested as follows: test flasks of 1140 ml volume; dosage of soil inoculum: 30 g dry matter of soil and 30 g inert material (Perlite or other possessing comparable properties), soil moisture content approximately 50%, weight of test sample 150-300mg with respect to the anticipated biodegradability. A frequency of analyses for CO sub(2) or O sub(2) content in the gaseous phase was selected so as to preserve aerobic conditions for tests (minimum 6 vol% O sub(2)). Aeration (so-called "refresh") was performed whenever the O sub(2) content in the gaseous phase of the closed flasks decreased. Under these conditions, the replacement of GC, IR and titration methods for determining CO sub(2) was verified in tests with a reference substrate, poly- beta -hydroxybutyrate (PHB), and model samples (polysaccharide Xanthan, microcrystalline cellulose Avicel). Biodegradation was evaluated by CO sub(2) produced (D sub(CO2)) and O sub(2) consumed (D sub(O2)). Differences among values of D sub(CO2) were less than 5%. Differences between D sub(CO2) and D sub(O2) values (determined by GC analysis) were on a level not exceeding 10%. The selected test conditions for IR or GC determination of CO sub(2) and/or paramagnetic or GC determination of O sub(2) proved to be suitable for examining the biodegradability of substances in soils.
The subject of this study was the verification of various alternatives for testing the biodegradability of polymers under soil conditions. The aim was to use gas chromatography to analyse the gaseous phase (CO2 and O2 content), a Micro-Oxymax respirometer (IR analysis of CO2, analysis of O2 by paramagnetic analyser) to observe the biodegradation of polymeric substances in a soil environment in closed test flasks, and to compare measured results with a standard acidimetric procedure for determining CO2. The experimental conditions of tests in soil were suggested as follows: test flasks of 1140ml volume; dosage of soil inoculum: 30g dry matter of soil and 30g inert material (Perlite or other possessing comparable properties), soil moisture content approximately 50%, weight of test sample 150-300mg with respect to the anticipated biodegradability. A frequency of analyses for CO2 or O2 content in the gaseous phase was selected so as to preserve aerobic conditions for tests (minimum 6vol% O2). Aeration (so-called 'refresh') was performed whenever the O2 content in the gaseous phase of the closed flasks decreased. Under these conditions, the replacement of GC, IR and titration methods for determining CO2 was verified in tests with a reference substrate, poly-beta-hydroxybutyrate (PHB), and model samples (polysaccharide Xanthan, microcrystalline cellulose Avicel). Biodegradation was evaluated by CO2 produced (DCO2) and O2 consumed (DO2). Differences among values of DCO2 were less than 5%. Differences between DCO2 and DO2 values (determined by GC analysis) were on a level not exceeding 10%. The selected test conditions for IR or GC determination of CO2 and/or paramagnetic or GC determination of O2 proved to be suitable for examining the biodegradability of substances in soils.
The subject of this study was the verification of various alternatives for testing the biodegradability of polymers under soil conditions. The aim was to use gas chromatography to analyse the gaseous phase (CO 2 and O 2 content), a Micro-Oxymax respirometer (IR analysis of CO 2, analysis of O 2 by paramagnetic analyser) to observe the biodegradation of polymeric substances in a soil environment in closed test flasks, and to compare measured results with a standard acidimetric procedure for determining CO 2. The experimental conditions of tests in soil were suggested as follows: test flasks of 1140 ml volume; dosage of soil inoculum: 30 g dry matter of soil and 30 g inert material (Perlite or other possessing comparable properties), soil moisture content approximately 50%, weight of test sample 150–300 mg with respect to the anticipated biodegradability. A frequency of analyses for CO 2 or O 2 content in the gaseous phase was selected so as to preserve aerobic conditions for tests (minimum 6 vol% O 2). Aeration (so-called “refresh”) was performed whenever the O 2 content in the gaseous phase of the closed flasks decreased. Under these conditions, the replacement of GC, IR and titration methods for determining CO 2 was verified in tests with a reference substrate, poly- β-hydroxybutyrate (PHB), and model samples (polysaccharide Xanthan, microcrystalline cellulose Avicel). Biodegradation was evaluated by CO 2 produced ( D CO 2 ) and O 2 consumed ( D O 2 ). Differences among values of D CO 2 were less than 5%. Differences between D CO 2 and D O 2 values (determined by GC analysis) were on a level not exceeding 10%. The selected test conditions for IR or GC determination of CO 2 and/or paramagnetic or GC determination of O 2 proved to be suitable for examining the biodegradability of substances in soils.
Author Hoffmann, Jaromír
Družbík, Martin
Dřímal, Pavel
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  surname: Družbík
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Issue 6
Keywords Biodegradation
Gas chromatography
Acidimetry
Soil tests
IR spectroscopy
Biological properties
Microcrystalline material
Aerobiosis
Biodegradability
Ageing
Cellulose
Carbon dioxide
Ester polymer
Xanthan gum
Butyrate(hydroxy)polymer
Experimental study
Soils
Analysis method
Aliphatic polymer
Oside polymer
Fourier-transformed infrared spectrometry
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Snippet The subject of this study was the verification of various alternatives for testing the biodegradability of polymers under soil conditions. The aim was to use...
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SubjectTerms Acidimetry
Applied sciences
Biodegradation
Exact sciences and technology
Gas chromatography
IR spectroscopy
Physical properties
Polymer industry, paints, wood
Properties and testing
Soil tests
Technology of polymers
Title Evaluating the aerobic biodegradability of plastics in soil environments through GC and IR analysis of gaseous phase
URI https://dx.doi.org/10.1016/j.polymertesting.2007.03.008
https://www.proquest.com/docview/19456510
https://www.proquest.com/docview/30115469
Volume 26
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