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Conference abstract2008

Controls of carbon exchange in a boreal minerogenic mire

Nilsson Mats, Sagerfors Jörgen, Buffam Ishi, Eriksson Tobias, Grelle Achim, klemedtsson Leif, Weslien Per, Laudon Hjalmar, Lindroth Anders

Abstract

Based on theories on both mire development and their response to environmental change, the current role of mires as a net carbon sink has been questioned. A rigorous evaluation of the contemporary net C-exchange in mires requires direct measurements of all relevant fluxes. We use data on carbon exchange from a boreal minerogenic oligotrophic mire (Degerö Stormyr, 64°11’ N, 19°33E) to derive a contemporary carbon budget and to analyze the main controls on the C exchange. Data on the following fluxes were collected: land-atmosphere CO2 (continuous Eddy Covariance measurements, 7 years) and CH4 (static chambers during the snow free period, 4 years) exchange; DOC in precipitation; loss of TOC, CO2 and CH4 through water runoff, 4 years (continuous discharge measurement and regular C-content measurements). The annual land atmosphere exchange of CO2 (NEE) was fairly constant between years and varied between -48 – -61 gCm-2yr-1 during six out of the seven years, despite a large variation in weather combinations, the average being -53±5 gCm-2yr-1. Of the net fixation of atmospheric CO2-C during the net uptake period, i.e. the growing season, approximately a third was lost during the net source period, i.e. the winter period. During the four years with measurements of methane and runoff C-export another third of the growing season uptake was lost from the mire ecosystem as methane and runoff C. While the balance between the length of the NEE uptake and the NEE loss period are most important for the annual net ecosystem carbon balance (NECB) it is central to understand the controls of the spring-summer, and the summer-autumn transitions. The onset of the net C uptake period was controlled by the interaction between the water content and the temperature of the peat moss surface. We interpret this as mainly being a control of the CO2 photosynthesis uptake by the Sphagnum mosses. The transition from being a net C sink to being a net C source is in contrast only controlled by the soil temperature. The higher the soil temperature during the months preceding the transition the earlier the mire will shift from being a C sink to become a C source. Our interpretation is that this transition is mainly controlled by the activity of the heterotrophic microorganisms. The transition from sink to source occur relatively late in the autumn with limited amount of incoming light resulting in a relatively low photosynthesis. During a year with exceptional dry late summer the NEE dropped to -17 gCm-2yr-1, compared to -53±5 gCm-2yr-1 during “normal” years. During this period the water table level was approximately 15 cm below the long-term lowest level. Data indicate that most of the reduction in NEE comes from decreased GPP while the ecosystem respiration was relatively stable between years. Including all component fluxes the mire still is a sink of atmospheric C during average weather conditions. During the years 2004 and 2005 the Net Ecosystem Balance (NECB) was -20±3.3 gCm-2yr-1. Both emission of methane and runoff export of carbon contributed significantly to the loss of carbon. During the dry year with a NEE of -17 gCm-2yr-1 the methane emission and runoff C export resulted in a NECB not different from 0

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Conference

2008 AGU Fall Meeting