Pyrolysis- and Chemical Degradation-GC/MS Analyses of Environmental Kerogen and Humic Substances and Their Applications to Geochemistry
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- YAMAMOTO Shuichi
- Department of Environmental Engineering for Symbiosis, Faculty of Engineering, Soka University
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- YOSHIOKA Hideyoshi
- Institute for Geo-Resources and Environment, National Institute of Advanced Industrial Science and Technology
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- ISHIWATARI Ryoshi
- 東京都立大学名誉教授
Bibliographic Information
- Other Title
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- 環境中のケロジェン及び腐植物質の熱分解及び化学分解ガスクロマトグラフィー/質量分析法と地球化学への応用
- カンキョウ チュウ ノ ケロジェン オヨビ フショク ブッシツ ノ ネツ ブンカイ オヨビ カガク ブンカイ ガス クロマトグラフィー シツリョウ ブンセキホウ ト チキュウ カガク エ ノ オウヨウ
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Description
A brown complex or refractory organic materials, which are often called humic substances and kerogen, are ubiquitous in aquatic and terrestrial environments. They play an important role in carbon and material cycles in the environment. Although a clear understanding of their molecular nature is essential, some knowledge of their chemical structure and the mechanism by which they form and change in time on Earth is still limited. The molecular characterization of these materials is difficult due to their insolubility and complex macromolecular nature. From this review, we highlight the following three types of chemical degradation techniques, which are becoming popular in the molecular characterization of these organic materials: i.e. pyrolysis gas chromatography-mass spectrometry (py-GCMS), pyrolysis in the presence of tetramethylammonium hydroxide coupled to gas chromatography-mass spectrometry (py-TMAH-GCMS), and gas chromatography-mass spectrometry after bond-selective chemical degradation (chemical degradation-GCMS). Both py-GCMS and py-TMAH-GCMS are often used as small-scale analytical methods. py-GCMS is commonly suitable for materials (e.g. kerogen in rocks) that produce non-polar or less-polar materials (e.g. hydrocarbons) on pyrolysis, while this technique may not be suitable for young humic substances, because they tend to produce polar materials by a thermal reaction of heteroatomic (such as oxygen, nitrogen) functional groups. py-TMAH-GCMS overcomes some of the weak points of py-GCMS. Since this technique is based on the cleavage of labile C-O bonds, such as ester, amide and ether bonds with simultaneous methylation (thermochemolysis), it can be applied for characterizing macromolecular organic matter, which is on the way of change from biomacromolecules (e.g. lignin, proteins, carbohydrates and lipids). Modern sequential chemical degradation-GCMS techniques involving the successive cleavage of different types of bonds (S-C bond, ether bond, double bonds and sub-units linked to aromatic moieties etc.) in refractory organic materials are described.<br>
Journal
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- BUNSEKI KAGAKU
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BUNSEKI KAGAKU 56 (2), 71-91, 2007
The Japan Society for Analytical Chemistry
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Keywords
Details 詳細情報について
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- CRID
- 1390001204354006912
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- NII Article ID
- 110006202056
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- NII Book ID
- AN00222633
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- COI
- 1:CAS:528:DC%2BD2sXitVyjt70%3D
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- NDL BIB ID
- 8683653
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- ISSN
- 05251931
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- Text Lang
- ja
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- Data Source
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- JaLC
- NDL
- Crossref
- NDL-Digital
- CiNii Articles
- KAKEN
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- Abstract License Flag
- Disallowed
