Temperature Sensitivity Indicates That Chlorination of Organic Matter in Forest Soil Is Primarily Biotic

Old assumptions that chloride is inert and that most chlorinated organic matter in soils is anthropogenic have been challenged by findings of naturally formed organochlorines. Such natural chlorination has been recognized for several decades, but there are still very few measurements of chlorination...

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Bibliographic Details
Published in:Environmental science & technology 2009-05, Vol.43 (10), p.3569-3573
Main Authors: Bastviken, David, Svensson, Teresia, Karlsson, Susanne, Sandén, Per, Öberg, Gunilla
Format: Article
Language:English
Subjects:
Aerobiosis
Anaerobiosis
Applied sciences
bound chlorine
catchment
Chlorine
Chlorine - metabolism
chloroacetic acids
chloroform
degradation
Earth sciences
emissions
Environmental Processes
Enzymes - metabolism
Exact sciences and technology
Forest soils
Forests
Geovetenskap
Halogenation
NATURAL SCIENCES
NATURVETENSKAP
Organic Chemicals - metabolism
organochlorines
Oxygen - metabolism
Pollution
retention
Soil
Soil mechanics
Soil sciences
Soils
sweden
Temperature
Trees - chemistry
Volatilization
weathering plant-material
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Summary:Old assumptions that chloride is inert and that most chlorinated organic matter in soils is anthropogenic have been challenged by findings of naturally formed organochlorines. Such natural chlorination has been recognized for several decades, but there are still very few measurements of chlorination rates or estimates of the quantitative importance of terrestrial chlorine transformations. While much is known about the formation of specific compounds, bulk chlorination remains poorly understood in terms of mechanisms and effects of environmental factors. We quantified bulk chlorination rates in coniferous forest soil using 36Cl-chloride in tracer experiments at different temperatures and with and without molecular oxygen (O2). Chlorination was enhanced by the presence of O2 and had a temperature optimum at 20 °C. Minimum rates were found at high temperatures (50 °C) or under anoxic conditions. The results indicate (1) that most of the chlorination between 4 and 40 °C was biotic and driven by O2 dependent enzymes, and (2) that there is also slower background chlorination occurring under anoxic conditions at 20 °C and under oxic conditions at 50 °C. Hence, while oxic and biotic chlorination clearly dominated, chlorination by other processes including possible abiotic reactions was also detected.
ISSN:0013-936X
1520-5851
1520-5851
DOI:10.1021/es8035779