Methane Production Rate during Anoxic Litter Decomposition Depends on Si Mass Fractions, Nutrient Stoichiometry, and Carbon Quality.

Annkathrin Hömberg,Klaus-Holger Knorr,Jörg Schaller

doi:10.3390/plants10040618

Annkathrin Hömberg, Klaus-Holger Knorr + Show 1 more

Open Access

https://doi.org/10.3390/plants10040618

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Abstract

While Si influences nutrient stoichiometry and decomposition of graminoid litter, it is still unclear how Si influences anoxic litter decomposition and CH4 formation in graminoid dominated fen peatlands. First, Eriophorum vaginatum plants were grown under different Si and P availabilities, then shoots and roots were characterized regarding their proportions of C, Si, N and P and regarding C quality. Subsequently the Eriophorum shoots were subjected to anoxic decomposition. We hypothesized; that (I) litter grown under high Si availability would show a higher Si but lower nutrient mass fractions and a lower share of recalcitrant carbon moieties; (II) high-Si litter would show higher CH4 and CO2 production rates during anoxic decomposition; (III) methanogenesis would occur earlier in less recalcitrant high-Si litter, compared to low-Si litter. We found a higher Si mass fraction that coincides with a general decrease in C and N mass fractions and decreased share of recalcitrant organic moieties. For high-Si litter, the CH4 production rate was higher, but there was no long-term influence on the CO2 production rate. More labile high-Si litter and a differential response in nutrient stoichiometry led to faster onset of methanogenesis. This may have important implications for our understanding of anaerobic carbon turnover in graminoid-rich fens.

Highlights

Accepted: 19 March 2021During the postglacial period, northern peatlands began acting as great carbon (C)sinks, comprising a C pool of >500 Gt of C [1], while covering only about 3% of the earth’s land surface [2]
Decomposition of peat, which governs the release of dissolved organic carbon (DOC)
Our study revealed some general differences between the investigated species concerning Si uptake and its effects on other nutrients stoichiometry

Summary

Introduction

Sinks, comprising a C pool of >500 Gt of C [1], while covering only about 3% of the earth’s land surface [2]. This C accumulation occurs because once grown organic matter reaches the permanently waterlogged, anoxic parts of the profile, the catotelm, decomposition proceeds much more slowly than under oxic conditions of the acrotelm [3]. Despite the function as C sink, peatlands are a source of greenhouse gasses such as carbon dioxide (CO2 ) and methane (CH4 ) [4]. Decomposition of peat, which governs the release of dissolved organic carbon (DOC) The aboveground biomass, which decomposes faster, is predominantly involved in respiration and methanogenesis and CH4 and CO2 production [5].

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