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 multilevel 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 of 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) (d.w. – dry weight); 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.