High Temporal and Spatial Variability of Atmospheric-Methane Oxidation in Alpine Glacier Forefield Soils

Glacier forefield soils can provide a substantial sink for atmospheric CH , facilitated by aerobic methane-oxidizing bacteria (MOB). However, MOB activity, abundance, and community structure may be affected by soil age, MOB location in different forefield landforms, and temporal fluctuations in soil physical parameters. We assessed the spatial and temporal variability of atmospheric-CH oxidation in an Alpine glacier forefield during the snow-free season of 2013. We quantified CH flux in soils of increasing age and in different landforms (sandhill, terrace, and floodplain forms) by using soil gas profile and static flux chamber methods. To determine MOB abundance and community structure, we employed gene-based quantitative PCR and targeted amplicon sequencing. Uptake of CH increased in magnitude and decreased in variability with increasing soil age. Sandhill soils exhibited CH uptake rates ranging from -3.7 to -0.03 mg CH m day Floodplain and terrace soils exhibited lower uptake rates and even intermittent CH emissions. Linear mixed-effects models indicated that soil age and landform were the dominating factors shaping CH flux, followed by cumulative rainfall (weighted sum ≤4 days prior to sampling). Of 31 MOB operational taxonomic units retrieved, ∼30% were potentially novel, and ∼50% were affiliated with upland soil clusters gamma and alpha. The MOB community structures in floodplain and terrace soils were nearly identical but differed significantly from the highly variable sandhill soil communities. We concluded that soil age and landform modulate the soil CH sink strength in glacier forefields and that recent rainfall affects its short-term variability. This should be taken into account when including this environment in future CH inventories. Oxidation of methane (CH ) in well-drained, "upland" soils is an important mechanism for the removal of this potent greenhouse gas from the atmosphere. It is largely mediated by aerobic, methane-oxidizing bacteria (MOB). Whereas there is abundant information on atmospheric-CH oxidation in mature upland soils, little is known about this important function in young, developing soils, such as those found in glacier forefields, where new sediments are continuously exposed to the atmosphere as a result of glacial retreat. In this field-based study, we investigated the spatial and temporal variability of atmospheric-CH oxidation and associated MOB communities in Alpine glacier forefield soils, aiming at better understan