Abstract
Boreal forests occupy nearly one fifth of the terrestrial land surface and are recognised as globally important regulators of carbon (C) cycling and greenhouse gas emissions. Carbon sequestration processes in these forests include assimilation of CO2 into biomass and subsequently into soil organic matter, and soil microbial oxidation of methane (CH4). In this study we explored how ecosystem retrogression, which drives vegetation change, regulates the important process of soil CH4 oxidation in boreal forests. We measured soil CH4 oxidation processes on a group of 30 forested islands in northern Sweden differing greatly in fire history, and collectively representing a retrogressive chronosequence, spanning 5000 years. Across these islands the build-up of soil organic matter was observed to increase with time since fire disturbance, with a significant correlation between greater humus depth and increased net soil CH4 oxidation rates. We suggest that this increase in net CH4 oxidation rates, in the absence of disturbance, results as deeper humus stores accumulate and provide niches for methanotrophs to thrive. By using this gradient we have discovered important regulatory controls on the stability of soil CH4 oxidation processes that could not have not been explored through shorter-term experiments. Our findings indicate that in the absence of human interventions such as fire suppression, and with increased wildfire frequency, the globally important boreal CH4 sink could be diminished.
Highlights
The Earth’s boreal forests lie between 45° and 70°N and account for one third of all forested lands [1], covering between 9–12 million km2
We propose that this effect is mediated by successional changes in the plant community since fire disturbance
The observed rates of ex situ CH4 oxidation from the deep cores was lower than the previous in situ and ex situ measurements made during the previous year, net CH4 oxidation rates were in the order Late > Mid > Early successional islands (Table 2)
Summary
The Earth’s boreal forests lie between 45° and 70°N and account for one third of all forested lands [1], covering between 9–12 million km2. The effect of time elapsed since last wildfire event on in situ net soil CH4 fluxes was examined using a static chamber method (n = 5 per island, 30 islands). The build-up of soil organic matter was observed to increase significantly with time since fire disturbance (R2 = 0.41; P 0.001), with a significant correlation between greater humus depth and net soil CH4 oxidation rates (R2 = 0.35; P 0.001; Fig 2).
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