Non-microbial methane formation in oxic soils
Alke Jugold,Frederik Althoff,M. Hurkuck,Markus Greule,Katharina Lenhart,Jos Lelieveld,Frank Keppler +6 more
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In this paper, the authors provide evidence for non-microbial methane formation in soils under oxic conditions, and suggest that chemical formation of methane during degradation of soil organic matter may represent the missing soil source that is needed to fully understand the methane cycle in aerobic soils.Abstract:
. Methane plays an important role as a radiatively and chemically active gas in our atmosphere. Until recently, sources of atmospheric methane in the biosphere have been attributed to strictly anaerobic microbial processes during degradation of organic matter. However, a large fraction of methane produced in the anoxic soil layers does not reach the atmosphere due to methanotrophic consumption in the overlaying oxic soil. Although methane fluxes from aerobic soils have been observed, an alternative source other than methanogenesis has not been identified thus far. Here we provide evidence for non-microbial methane formation in soils under oxic conditions. We found that soils release methane upon heating and other environmental factors like ultraviolet irradiation, and drying-rewetting cycles. We suggest that chemical formation of methane during degradation of soil organic matter may represent the missing soil source that is needed to fully understand the methane cycle in aerobic soils. Although the emission fluxes are relatively low when compared to those from wetlands, they may be important in warm and wet regions subjected to ultraviolet radiation. We suggest that this methane source is highly sensitive to global change.read more
Citations
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Journal ArticleDOI
Aquatic and terrestrial cyanobacteria produce methane.
Mina Bižić,T. Klintzsch,Danny Ionescu,Muna Hindiyeh,Marco Günthel,Marco Günthel,Alicia M. Muro-Pastor,Werner Eckert,Tim Urich,Frank Keppler,Hans-Peter Grossart,Hans-Peter Grossart +11 more
TL;DR: It is suggested that the formation of methane by cyanobacteria contributes to methane accumulation in oxygen-saturated marine and limnic surface waters, and contributes to global warming potentially having a direct positive feedback on climate change.
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Methane Production in Oxic Lake Waters Potentially Increases Aquatic Methane Flux to Air
TL;DR: Active methane production in oxygenated lake waters challenges the long-standing paradigm that microbial methane production occurs only under anoxic conditions and forces us to rethink the ecology and environmental dynamics of this powerful greenhouse gas as mentioned in this paper.
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Fenton chemistry and reactive oxygen species in soil: Abiotic mechanisms of biotic processes, controls and consequences for carbon and nutrient cycling
Guanghui Yu,Yakov Kuzyakov +1 more
TL;DR: In this paper, the fundamental Eh-pH diagrams for reactive oxygen species (ROS) were calculated for Fenton reactions under specific soil conditions and showed their relevance for ROS species.
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A novel pathway of direct methane production and emission by eukaryotes including plants, animals and fungi: An overview
TL;DR: There is an urgent need to identify the precursors for this novel CH 4 source and improve the understanding of the mechanisms of direct CH 4 production and the impacts of environmental stresses.
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Physical and biological controls on trace gas fluxes in semi-arid urban ephemeral waterways
E. L. Gallo,E. L. Gallo,Kathleen A. Lohse,Kathleen A. Lohse,Christopher M. Ferlin,Thomas Meixner,Paul D. Brooks +6 more
TL;DR: In this paper, the authors measured carbon dioxide (CO2), nitrous oxide (N2O), and methane (CH4) before and after soil wetting in 16 ephemeral stream channels that vary in soil texture and organic matter in Tucson, AZ.
References
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