Comparative ecosystem-atmosphere exchange of energy and mass in a European Russian and a central Siberian bog II. Interseasonal and interannual variability of CO2 fluxes

Arneth, Almut; Kurbatova, Juliya; Kolle, Olaf; Shibistova, Olga; Lloyd, Jon; Vygodskaya, N. N.; Schulze, Ernst Detlef

doi:10.1034/j.1600-0889.2002.01349.x

Cited by 97 publications

(120 citation statements)

References 60 publications

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“…the transformation of these stands from sources into sinks of CO 2 or vice versa. This corresponds to the observed results that an ecosystem being close to the equilibrium actually can be sink or source of CO 2 in different years depending on weather conditions (e.g., Arneth et al, 2002).…”

Section: Discussionsupporting

confidence: 80%

Effect of climate change and nitrogen deposition on central-European forests: Regional-scale simulation for South Bohemia

Tatarinov

Cienciala

Vopěnka

et al. 2011

Forest Ecology and Management

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Section: Discussionsupporting

confidence: 80%

Effect of climate change and nitrogen deposition on central-European forests: Regional-scale simulation for South Bohemia

Tatarinov

Cienciala

Vopěnka

et al. 2011

Forest Ecology and Management

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“…Some studies identified WTD as the major control on net ecosystem CO 2 exchange (NEE) or its component fluxes of photosynthesis [gross ecosystem exchange (GEE)] and total ecosystem respiration (R eco ) (e.g., Arneth et al, 2002). Other studies concluded that WTD was a less important control than light, and air (T air ) or soil temperature (T soil ) (e.g.…”

Section: Introductionmentioning

confidence: 98%

On the relationship between water table depth and water vapor and carbon dioxide fluxes in a minerotrophic fen

Sonnentag

Kamp

Barr

et al. 2010

Global Change Biology

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The focus of this study is the relationship between water table depth (WTD) and water vapor [evapotranspiration (ET)] and carbon dioxide [CO 2 ; net ecosystem exchange (NEE)] fluxes in a fen in western Canada. We analyzed hydrological and eddy covariance measurements from four snow-free periods (2003)(2004)(2005)(2006) with contrasting meteorological conditions to establish the link between daily WTD and ET and gross ecosystem CO 2 exchange (GEE) and ecosystem respiration (R eco ; NEE 5 R eco ÀGEE), respectively: 2003 was warm and dry, 2004 was cool and wet, and 2005 and 2006 were both wet. In 2003, the water table (WT) was below the ground surface. In 2004, the WT rose above the ground surface, and in 2005 and 2006, the WT stayed well above the ground surface. There were no significant differences in total ET ($ 316 mm period À1 ), but total NEE was significantly different (2003: 8 g C m À2 period À1 ; 2004: À139 g C m À2 period À1 ; 2005: À163 g C m À2 period À1 ; 2006: À195 g C m À2 period À1 ), mostly due to differences in total GEE (2003: 327 g C m À2 period À1 ; 2004: 513 g C m À2 period À1 ; 2005: 411 g C m À2 period À1 ; 2006: 556 g C m À2 period À1 ). Variation in ET is mostly explained by radiation (67%), and the contribution of WTD is only minor (33%). WTD controls the compensating contributions of different land surface components, resulting in similar total ET regardless of the hydrological conditions. WTD and temperature each contribute about half to the explained variation in GEE up to a threshold ponding depth, below which temperature alone is the key explanatory variable. WTD is only of minor importance for the variation in R eco , which is mainly controlled by temperature. Our study implies that future peatland modeling efforts explicitly consider topographic and hydrogeological influences on WTD.

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“…These parameters were held constant across the domain. We calibrated these parameters using CO 2 flux observations for the year 2000 from the Zotino Bog eddy covariance tower (Arneth et al, 2002), denoted with a yellow star in Fig. 1.…”

Section: Biogeochemistrymentioning

confidence: 99%

Modeling the large-scale effects of surface moisture heterogeneity on wetland carbon fluxes in the West Siberian Lowland

et al. 2013

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Abstract. We used a process-based model to examine the role of spatial heterogeneity of surface and sub-surface water on the carbon budget of the wetlands of the West Siberian Lowland over the period 1948-2010. We found that, while surface heterogeneity (fractional saturated area) had little overall effect on estimates of the region's carbon fluxes, subsurface heterogeneity (spatial variations in water table depth) played an important role in both the overall magnitude and spatial distribution of estimates of the region's carbon fluxes. In particular, to reproduce the spatial pattern of CH 4 emissions recorded by intensive in situ observations across the domain, in which very little CH 4 is emitted north of 60 • N, it was necessary to (a) account for CH 4 emissions from unsaturated wetlands and (b) use spatially varying methane model parameters that reduced estimated CH 4 emissions in the northern (permafrost) half of the domain (and/or account for lower CH 4 emissions under inundated conditions). Our results suggest that previous estimates of the response of these wetlands to thawing permafrost may have overestimated future increases in methane emissions in the permafrost zone.

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Comparative ecosystem-atmosphere exchange of energy and mass in a European Russian and a central Siberian bog II. Interseasonal and interannual variability of CO2 fluxes

Cited by 97 publications

References 60 publications

Effect of climate change and nitrogen deposition on central-European forests: Regional-scale simulation for South Bohemia

Effect of climate change and nitrogen deposition on central-European forests: Regional-scale simulation for South Bohemia

On the relationship between water table depth and water vapor and carbon dioxide fluxes in a minerotrophic fen

Modeling the large-scale effects of surface moisture heterogeneity on wetland carbon fluxes in the West Siberian Lowland

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