Abiotic methanogenesis from organosulphur compounds under ambient conditions

Althoff, Frederik; Benzing, K.; Comba, Peter; McRoberts, Colin; Boyd, Derek R.; Greiner, Steffen; Keppler, Frank

doi:10.1038/ncomms5205

Cited by 109 publications

(165 citation statements)

References 56 publications

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“…2d). However, this observation is in line with some previous findings (Althoff et al, 2010(Althoff et al, , 2014, who showed that the abiotic formation of CH 4 due to the degradation of methionine or ascorbic acid by light or oxidants such as iron minerals is possible. In the case of methionine, it was shown that the sulfur-bound methyl group of Met was the carbon precursor of CH 4 (Althoff et al, 2014).…”

Section: Inorganic and Organic Precursors Of Chsupporting

confidence: 80%

Evidence for methane production by the marine algae <i>Emiliania huxleyi</i>

et al. 2016

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Abstract. Methane (CH 4 ), an important greenhouse gas that affects radiation balance and consequently the earth's climate, still has uncertainties in its sinks and sources. The world's oceans are considered to be a source of CH 4 to the atmosphere, although the biogeochemical processes involved in its formation are not fully understood. Several recent studies provided strong evidence of CH 4 production in oxic marine and freshwaters, but its source is still a topic of debate. Studies of CH 4 dynamics in surface waters of oceans and large lakes have concluded that pelagic CH 4 supersaturation cannot be sustained either by lateral inputs from littoral or benthic inputs alone. However, regional and temporal oversaturation of surface waters occurs frequently. This comprises the observation of a CH 4 oversaturating state within the surface mixed layer, sometimes also termed the "oceanic methane paradox". In this study we considered marine algae as a possible direct source of CH 4 . Therefore, the coccolithophore Emiliania huxleyi was grown under controlled laboratory conditions and supplemented with two 13 C-labeled carbon substrates, namely bicarbonate and a position-specific 13 C-labeled methionine (R-S-13 CH 3 ). The CH 4 production was 0.7 µg particular organic carbon (POC) g −1 d −1 , or 30 ng g −1 POC h −1 . After supplementation of the cultures with the 13 C-labeled substrate, the isotope label was observed in headspace CH 4 . Moreover, the absence of methanogenic archaea within the algal culture and the oxic conditions during CH 4 formation suggest that the widespread marine algae Emiliania huxleyi might contribute to the observed spatially and temporally restricted CH 4 oversaturation in ocean surface waters.

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Section: Inorganic and Organic Precursors Of Chsupporting

confidence: 80%

Evidence for methane production by the marine algae <i>Emiliania huxleyi</i>

et al. 2016

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“…An interesting recently described reaction, related to published work on demethylation and well-studied sulfoxidation reactions, is methane formation from methionine under oxidative conditions. [118] As an example of these biomimetic studies with well-defined systems and their complexes, we describe a few processes of bispidine-type ligands relevant to environmental transformations, also because some of the environmentally relevant mechanistic work has been done with these ligands. Note that in soils, the relevant organic matter is humic substances, and these are believed to coordinate to Fe II and Fe III to enable chemical reactions similar to the structurally well-defined model systems described here.…”

Section: Relevant Oxidation Reactionsmentioning

confidence: 99%

“…[108][109][110][111][112][113] A wide variety of published work on the stoichiometric and catalytic oxidation of organic molecules with low-molecularweight non-heme iron model complexes is available, [57,114,115] and this includes oxygen-transfer reactions, e.g. sulfoxidation, [91,116] oxidative demethylation, [117] and methane formation [118] as well as the oxidation of alkanes and alkenes, [91] which are of specific interest in the degradation of organic matter in nature. An interesting recently described reaction, related to published work on demethylation and well-studied sulfoxidation reactions, is methane formation from methionine under oxidative conditions.…”

Section: Relevant Oxidation Reactionsmentioning

confidence: 99%

“…Cl À or a species derived from H 2 O, e.g. OH À ): (1) olefin epoxidation and cis-dihydroxylation, [84,121] (2) cyclohexane oxidation, [92,120] and (3) halogenation, [89,118] (4) sulfoxidation, [116] (5) catechol oxidation [113] and (6) furan formation. [169] …”

Section: Modelling Of the Catalytically Active Iron Speciesmentioning

confidence: 99%

“…Based on studies with several phenolic derivatives (catechol, hydroquinone, and recorcinol), [166,167] [159] (2) chloroethene and chloroalkanes, [160] (3) chlorinated acetic acid, [118,161] (4) muconic, formic, acetic, oxalic, malonic, fumaric and maleic acids, [162][163][164] (5) chloroethyne, [165] (6) carbon suboxide, [166] (7) trihalomethanes, [167] (8) furan. [168,169] In the corresponding enzymes and model systems, the iron species are transformed to the resting state, top left.…”

Section: Modelling Of the Catalytically Active Iron Speciesmentioning

confidence: 99%

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Iron-catalysed oxidation and halogenation of organic matter in nature

et al. 2015

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Environmental context. Natural organohalogens produced in and released from soils are of utmost importance for ozone depletion in the stratosphere. Formation mechanisms of natural organohalogens are reviewed with particular attention to recent advances in biomimetic chemistry as well as in radical-based Fenton chemistry. Iron-catalysed oxidation in biotic and abiotic systems converts organic matter in nature to organohalogens.Abstract. Natural and anthropogenic organic matter is continuously transformed by abiotic and biotic processes in the biosphere. These reactions include partial and complete oxidation (mineralisation) or reduction of organic matter, depending on the redox milieu. Products of these transformations are, among others, volatile substances with atmospheric relevance, e.g. CO 2 , alkanes and organohalogens. Natural organohalogens, produced in and released from soils and salt surfaces, are of utmost importance for stratospheric (e.g. CH 3 Cl, CH 3 Br for ozone depletion) and tropospheric (e.g. Br 2 , BrCl, Cl 2 , HOCl, HOBr, ClNO 2 , BrNO 2 and BrONO 2 for the bromine explosion in polar, marine and continental boundary layers, and I 2 , CH 3 I, CH 2 I 2 for reactive iodine chemistry, leading to new particle formation) chemistry, and pose a hazard to terrestrial ecosystems (e.g. halogenated carbonic acids such as trichloroacetic acid). Mechanisms for the formation of volatile hydrocarbons and oxygenated as well as halogenated derivatives are reviewed with particular attention paid to recent advances in the field of mechanistic studies of relevant enzymes and biomimetic chemistry as well as radical-based processes.

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Visible‐Light Photoredox‐Catalyzed Thioacetalization of Aldehydes Under Metal‐Free and Solvent‐Free Conditions

Wang

Basha

et al. 2018

Adv Synth Catal

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A first visible-light photoredox-catalyzed thioacetalization of aldehydes under metal-free and solvent-free conditions is described. Under blue LED irradiation, a reactive thiyl radical was initially generated through single-electron oxidation of thiol, which subsequently reacted with aldehydes to afford dithioacetals following a radical mechanism. The reaction proceeded under ambient conditions, and a wide range of acyclic and cyclic dithioacetal derivatives were afforded in good to excellent yields.

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Abiotic methanogenesis from organosulphur compounds under ambient conditions

Cited by 109 publications

References 56 publications

Evidence for methane production by the marine algae <i>Emiliania huxleyi</i>

Evidence for methane production by the marine algae <i>Emiliania huxleyi</i>

Iron-catalysed oxidation and halogenation of organic matter in nature

Visible‐Light Photoredox‐Catalyzed Thioacetalization of Aldehydes Under Metal‐Free and Solvent‐Free Conditions

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Abiotic methanogenesis from organosulphur compounds under ambient conditions

Cited by 109 publications

References 56 publications

Evidence for methane production by the marine algae &lt;i&gt;Emiliania huxleyi&lt;/i&gt;

Evidence for methane production by the marine algae &lt;i&gt;Emiliania huxleyi&lt;/i&gt;

Iron-catalysed oxidation and halogenation of organic matter in nature

Visible‐Light Photoredox‐Catalyzed Thioacetalization of Aldehydes Under Metal‐Free and Solvent‐Free Conditions

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Evidence for methane production by the marine algae <i>Emiliania huxleyi</i>

Evidence for methane production by the marine algae <i>Emiliania huxleyi</i>