Large but variable methane production in anoxic freshwater sediment upon addition of allochthonous and autochthonous organic matter.

Charlotte Grasset,Fabio Roland,Raquel Mendonça,Gabriella Villamor Saucedo,David Bastviken,Sebastian Sobek

doi:10.1002/lno.10786

Charlotte Grasset, Fabio Roland + Show 4 more

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https://doi.org/10.1002/lno.10786

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Abstract

An important question in the context of climate change is to understand how CH4 production is regulated in anoxic sediments of lakes and reservoirs. The type of organic carbon (OC) present in lakes is a key factor controlling CH4 production at anoxic conditions, but the studies investigating the methanogenic potential of the main OC types are fragmented. We incubated different types of allochthonous OC (alloOC; terrestrial plant leaves) and autochthonous OC (autoOC; phytoplankton and two aquatic plants species) in an anoxic sediment during 130 d. We tested if (1) the supply of fresh alloOC and autoOC to an anoxic refractory sediment would fuel CH4 production and if (2) autoOC would decompose faster than alloOC. The addition of fresh OC greatly increased CH4 production and the δ13C‐CH4 partitioning indicated that CH4 originated exclusively from the fresh OC. The large CH4 production in an anoxic sediment fueled by alloOC is a new finding which indicates that all systems with anoxic conditions and high sedimentation rates have the potential to be CH4 emitters. The autoOC decomposed faster than alloOC, but the total CH4 production was not higher for all autoOC types, one aquatic plant species having values as low as the terrestrial leaves, and the other one having values as high as phytoplankton. Our study is the first to report such variability, suggesting that the extent to which C fixed by aquatic plants is emitted as greenhouse gases or buried as OC in sediment could more generally differ between aquatic vegetation types.

Highlights

An important question in the context of climate change is to understand how CH4 production is regulated in anoxic sediments of lakes and reservoirs
Allochthonous organic carbon (OC) is usually assumed to have a lower reactivity than autochthonous OC because compared to aquatic plants and phytoplankton, Methanogenic potential of different OC types terrestrial plants have more support tissues, rich in complex structural compounds (Rascio 2002; Dai et al 2005)
This study shows that large CH4 production can result from the addition of fresh OC to anoxic sediments, from autochthonous OC (autoOC), and from allochthonous OC (alloOC), within timescales of weeks to months

Summary

Introduction

An important question in the context of climate change is to understand how CH4 production is regulated in anoxic sediments of lakes and reservoirs. We incubated different types of allochthonous OC (alloOC; terrestrial plant leaves) and autochthonous OC (autoOC; phytoplankton and two aquatic plants species) in an anoxic sediment during 130 d. Allochthonous OC (alloOC, i.e., OC derived from land) is usually assumed to have a lower reactivity than autochthonous OC (autoOC, i.e., OC derived from aquatic production) because compared to aquatic plants and phytoplankton, Methanogenic potential of different OC types terrestrial plants have more support tissues, rich in complex structural compounds (Rascio 2002; Dai et al 2005). There is at present no comprehensive understanding of the effects of productivity, dominating aquatic vegetation type, and terrestrial OC input on CH4 emissions from lakes

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