Organohalogen emissions from saline environments – spatial extrapolation using remote sensing as most promising tool

Kotte, Karsten; Löw, Fabian; Huber, Stefan; Krause, Torsten; Mulder, Ines; Schöler, H. F.

doi:10.5194/bg-9-1225-2012

Cited by 15 publications

(17 citation statements)

References 40 publications

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“…Although most of these organohalogens have been discovered in the marine environment, various chemical and biological processes producing organohalogens have been identified in the terrestrial environment as well. The presence of volatile and non-volatile trihalomethyl compounds (especially trichloromethane, trichloroacetic acid, trichloroacetyl-containing compounds -the model compounds of this review) in unpolluted terrestrial environments has been shown in for example temperate forests, grasslands and peatlands (Hoekstra et al, 1999;Haselmann et al, 2000a;Dimmer et al, 2001;McCulloch, 2003;Peters, 2003;Albers et al, 2010a), boreal forests (Hellén et al, 2006), wet tundra (Rhew et al, 2008b), subtropical shrub lands and hypersaline arid soil (Kotte et al, 2012), salt marshes (Rhew et al, 2008a) and rice paddies (Khalil et al, 1990). The frequent detection of trichloromethyl compounds in soils and groundwater in absence of other anthropogenic contaminants suggests strongly that these halogenated compounds are produced naturally by biogeochemical processes (Laturnus et al, 2000;Albers et al, 2010a;Hunkeler et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Formation mechanisms of trichloromethyl-containing compounds in the terrestrial environment: A critical review

Breider

Albers

2015

Chemosphere

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Section: Introductionmentioning

confidence: 99%

Formation mechanisms of trichloromethyl-containing compounds in the terrestrial environment: A critical review

Breider

Albers

2015

Chemosphere

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“…This can be explained by the higher organic matter content in soils. Based on a 24-h production time under moist conditions and elevated summer temperatures leading to topsoil temperatures of up to 55 8C, [29] a soil density of 1.3 g cm À3 and 1-cm soil depth, our data are extrapolated to high MeCl production rates of 650 mmol m À2 day À1 . For comparison, Rhew et al [6] found similarly large MeCl fluxes from salt marshes of up to 570 mmol m À2 day À1 , but production was related to plant activity.…”

Section: Resultsmentioning

confidence: 99%

“…A rewetting and drying-out cycle is typical for SW Australian salt lakes. Kotte et al [29] reported high emissions of MeCl and MeBr from dry samples of similar environments in south Russia and Namibia. But areas of regressing (salt) lakes such as the Aral Sea could also contribute to thermolytic emissions.…”

Section: Assessment Of Thermolytic Dms and Mecl Formation In Hypersalmentioning

confidence: 98%

Thermolytic degradation of methylmethionine and implications for its role in DMS and MeCl formation in hypersaline environments

et al. 2015

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Environmental context. Methyl chloride and dimethyl sulfide are important atmospheric trace gases, but their biogeochemical contributions to the atmosphere are not fully understood. The amino acid derivative methyl methionine has been hypothesised to be a precursor of these two atmospheric gases, especially in drying saltlake environments. We found methyl chloride and dimethyl sulfide in salt crystals and soil samples of hypersaline lakes, suggesting that a thermal decay of methyl methionine could be one of the formation mechanisms responsible.Abstract. Volatile organic halocarbons (VOXs) and volatile organosulfur compounds (VOSCs) play an important role in the chemical processes of the lower atmosphere. However, biogeochemical release mechanisms from terrestrial environments are complex and the current knowledge of the origin and fluxes of these compounds is incomplete. This study presents data from worldwide sampling campaigns to hypersaline salt lakes to investigate terrestrial sources for atmospheric VOXs and VOSCs. The hypothesis was tested if methionine or methylmethionine could potentially serve as a precursor for methyl chloride and dimethyl sulfide formation in salt-lake environments. Next to methyl chloride, emissions from hypersaline soil samples incubated in headspace vials showed an array of VOSCs including dimethylsulfide and dimethyldisulfide. Additionally, methyl chloride and dimethyl sulfide were released from fluid inclusions of halite crystals after grinding and purge-and-trap headspace gas chromatography-mass spectrometry analysis. An abiotic mechanism for their formation is conceivable owing to the fast response of emission on heating freeze-dried samples at 40 8C. Furthermore, the compounds trapped in fluid inclusions of halite crystals correspond to those compounds originally formed in the immediately subjacent soils. Based on the thermolytic degradation of methylmethionine, the activation energies for methyl chloride and dimethyl sulfide are calculated from their Arrhenius plots. Additionally, structurally related substances were analysed and a degradation mechanism is postulated. Results indicate that thermolytic processes could play an important role in salt-lake environments on desiccation.

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“…A few years later, the organohalogen emissions from salt lakes and salt-affected soils were investigated on a broader scale by combining microcosm experiments and remote sensing. [28] For an area of 15 000 km 2 in the southern Aral Sea basin, fluxes of 16 873 g day À1 in the cover area for C 2 H 2 Cl 2 (dichloroethene) were estimated. Recently, it was shown that pH-neutral to alkaline hypersaline lake sediments from Western Australia also contribute to the global emissions of halogenated hydrocarbons and that biotic processes dominate the emissions.…”

mentioning

confidence: 99%

Halogenated hydrocarbon formation in a moderately acidic salt lake in Western Australia – role of abiotic and biotic processes

et al. 2015

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Environmental context. Volatile halogenated organic compounds (VOX) contribute to ozone depletion and global warming. Here we demonstrate that acidic salt lake sediments in Western Australia contribute to the global natural emission of these compounds and that the emissions are primarily of biotic origin. Elucidating major sources and sinks of VOX is a key task in environmental chemistry because their formation and degradation have major effects on atmospheric chemistry and thus earth climate.Abstract. Volatile organohalogen compounds (VOX) are known environmental pollutants and contribute to stratospheric ozone depletion. Natural formation of VOX has been shown for many environments from the deep sea to forest soils and Antarctica. Recently, we showed that VOX are emitted from pH-neutral salt lakes in Western Australia and that they are mainly of biotic origin. To which extent this biotic organohalogen formation in salt lakes is pH-dependent and whether VOX are also formed under acidic conditions are unknown. Therefore, we quantified VOX emissions from an acidic salt lake in Western Australia (Lake Orr) in biotic and abiotic (g ray-irradiated) microcosm experiments under controlled laboratory conditions. The experiments revealed that biotic halogenation processes also occurred under acidic conditions (pH range 3.8-4.8), though the emissions were approximately one order of magnitude lower (nanogram per kilogram dry sediment range) than from pH-neutral lake sediments. Among the detected substances were brominated, e.g. tribromomethane, as well as chlorinated compounds (e.g. trichloromethane). The addition of lactate and acetate, and ferrihydrite showed no stimulation of VOX formation in our microcosms. Hence, the stimulation of Fe-metabolising microorganisms and their potential effect on the formation of reactive Fe species did not promote VOX emissions, suggesting a direct enzymatic formation of the emitted compounds.

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Organohalogen emissions from saline environments – spatial extrapolation using remote sensing as most promising tool

Cited by 15 publications

References 40 publications

Formation mechanisms of trichloromethyl-containing compounds in the terrestrial environment: A critical review

Formation mechanisms of trichloromethyl-containing compounds in the terrestrial environment: A critical review

Thermolytic degradation of methylmethionine and implications for its role in DMS and MeCl formation in hypersaline environments

Halogenated hydrocarbon formation in a moderately acidic salt lake in Western Australia – role of abiotic and biotic processes

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