Your search keyword '"Schroth, M.H."' showing total 3 results

1. Technical Note: Disturbance of soil structure can lead to release of methane entrapped in glacier forefield soils

Author

Nauer P.A., Chiri E., Zeyer J., and Schroth M.H.

Abstract

Investigations of sources and sinks of atmospheric CH4 are needed to understand the global CH4 cycle and climate change mitigation options. Glaciated environments might play a critical role due to potential feedbacks with global glacial meltdown. In an emerging glacier forefield an ecological shift occurs from an anoxic potentially methanogenic subglacial sediment to an oxic proglacial soil in which soil microbial consumption of atmospheric CH4 is initiated. The development of this change in CH4 turnover can be quantified by soil gas profile analysis. We found evidence for CH4 entrapped in glacier forefield soils when comparing two methods for the collection of soil gas samples: a modified steel rod (SR) designed for one time sampling and rapid screening (samples collected 1 min after hammering the SR into the soil) and a novel multi level sampler (MLS) for repetitive sampling through a previously installed access tube (samples collected weeks after access tube installation). In glacier forefields on siliceous bedrock sub atmospheric CH4 concentrations were observed with both methods. Conversely elevated soil CH4 concentrations were observed in calcareous glacier forefields but only in samples collected with the SR while MLS samples all showed sub atmospheric CH4 concentrations. Time series SR soil gas sampling (additional samples collected 2 3 5 and 7 min after hammering) confirmed the transient nature of the elevated soil CH4 concentrations which were decreasing from 100 µL L 1 towards background levels within minutes. This hints towards the existence of entrapped CH4 in calcareous glacier forefield soil that can be released when sampling soil gas with the SR. Laboratory experiments with miniature soil cores collected from two glacier forefields confirmed CH4 entrapment in these soils. Treatment by sonication and acidification resulted in a massive release of CH4 from calcareous cores (on average 0.3 – 1.8 µg CH4 (g d.w.) 1); release from siliceous cores was 1 2 orders of magnitude lower (0.02 – 0.03 µg CH4 (g d.w.) 1). Clearly some form of CH4 entrapment exists in calcareous glacier forefield soils and to a much lesser extent in siliceous glacier forefield soils. Its nature and origin remain unclear and will be subject of future investigations.

Published

2014

2. Field-scale tracking of active methane-oxidizing communities in a landfill cover soil reveals spatial and seasonal variability

Author

Henneberger, R., Chiri, E., Bodelier, P.E.L., Frenzel, P., Lüke, C., Schroth, M.H., and Microbial Ecology (ME)

Subjects

Waste Disposal Facilities, Ecological Microbiology, international, Fatty Acids, Methylomonas, Seasons, Methane, Oxidation-Reduction, Soil Microbiology

Abstract

Aerobic methane-oxidizing bacteria (MOB) in soils mitigate methane (CH4 ) emissions. We assessed spatial and seasonal differences in active MOB communities in a landfill cover soil characterized by highly variable environmental conditions. Field-based measurements of CH4 oxidation activity and stable-isotope probing of polar lipid-derived fatty acids (PLFA-SIP) were complemented by microarray analysis of pmoA genes and transcripts, linking diversity and function at the field scale. In situ CH4 oxidation rates varied between sites and were generally one order of magnitude lower in winter compared with summer. Results from PLFA-SIP and pmoA transcripts were largely congruent, revealing distinct spatial and seasonal clustering. Overall, active MOB communities were highly diverse. Type Ia MOB, specifically Methylomonas and Methylobacter, were key drivers for CH4 oxidation, particularly at a high-activity site. Type II MOB were mainly active at a site showing substantial fluctuations in CH4 loading and soil moisture content. Notably, Upland Soil Cluster-gamma-related pmoA transcripts were also detected, indicating concurrent oxidation of atmospheric CH4 . Spatial separation was less distinct in winter, with Methylobacter and uncultured MOB mediating CH4 oxidation. We propose that high diversity of active MOB communities in this soil is promoted by high variability in environmental conditions, facilitating substantial removal of CH4 generated in the waste body.

Published

2014

3. Transport of methane and noble gases during gas push-pull tests in dry porous media

Author

Gonzalez-Gil, G., Schroth, M.H., and Zeyer, J.

Abstract

A field method called the gas push-pull test (GPPT) was previously developed and tested for the in situ quantification of aerobic methane (CH4) oxidation by soil microorganisms. The GPPT consists of an injection followed by extraction of reactant and tracer gases into and out of the soil. Quantification of microbial activities from GPPTs requires insight in the transport of reactant and tracer gases under diverse field conditions. We investigated how the transport of different tracer gases (He, Ne, and Ar) compares to that of the reactant gas CH4 during GPPTs conducted in a well-defined, dry porous media that mimicked an open system. Transport of gaseous components during GPPT is mainly driven by advection resulting from injection and extraction and diffusion driven by concentration gradients. Regardless of the advective component (selected injection/extraction, flow rates 0.2-0.8 L min-1), diffusion was the dominant transport mechanism for gaseous components. This resulted in dissimilar transport of CH4 and the tracers He and Ne. Numerical simulations of GPPTs showed that similar transport of these components is only achieved at very high injection/extraction rates that, in practice, are not feasible since they would imply extremely short duration times of GPPTs to allow for consumption of a measurable amount of reactant(s) by soil microorganisms. However, Ar transport was similar to that of CH4. Hence, Ar may be a good tracer provided that it is injected at high concentrations (e.g., >25% [v/v]) to overcome its background concentration in soil air. Using moderate injection/extraction rates (e.g., 0.6 L min-1) with injected volumes of 10-30 L will result in GPPT durations of 1-3 h, which would suffice to attain a measurable consumption of reactant(s) in soils having relatively high (e.g., first-order rate constants >0.3 h-1) microbial activities.