A data-driven analysis of energy balance closure across FLUXNET research sites: The role of landscape scale heterogeneity

Stoy, Paul C.; Mauder, Matthias; Foken, Thomas; Marcolla, Barbara; Boegh, Eva; Ibrom, Andreas; Arain, M. Altaf; Arneth, Almut; Aurela, Mika; Bernhofer, Christian; Cescatti, Alessandro; Dellwik, Ebba; Duce, Pierpaolo; Gianelle, Damiano; Gorsel, Eva van; Kiely, Gerard; Knohl, Alexander; Margolis, Hank A.; McCaughey, Harry; Merbold, Lutz; Montagnani, Leonardo; Papale, Dario; Reichstein, Markus; Saunders, Matthew; Serrano-Ortiz, Penélope; Sottocornola, Matteo; Spano, Donatella; Vaccari, Francesco Primo; Varlagin, Andrej

doi:10.1016/j.agrformet.2012.11.004

Cited by 500 publications

(402 citation statements)

References 203 publications

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“…The DC values for both sites are closer to the ideal value of 1 than the average DCs found in all published FLUXNET intercomparison studies to date, see Stoy et al (2013) and references therein. Compared to other low-vegetation experiments, the DC values are close to the median (0.9) found by Laubach and Teichmann (1999) reviewing 11 studies over grass or crops, close to the grassland average (0.86) reported by Stoy et al (2013) and comparable to those for three Australian grasslands (0.87, 0.86 and 0.94) given by Leuning et al (2012). To conclude, the surface energy budgets at our sites give no indication of any quality issues beyond what is commonly accepted as inevitable methodical error of the EC technique.…”

Section: J E Hunt Et Al: Carbon Budgets For An Irrigated and An Unmentioning

confidence: 77%

Carbon budgets for an irrigated intensively grazed dairy pasture and an unirrigated winter-grazed pasture

et al. 2016

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Abstract. Intensification of pastoral agriculture is occurring rapidly across New Zealand, including increasing use of irrigation and fertiliser application in some regions. While this enables greater gross primary production (GPP) and livestock grazing intensity, the consequences for the net ecosystem carbon budget (NECB) of the pastures are poorly known. Here, we determined the NECB over one year for an irrigated, fertilised and rotationally grazed dairy pasture and a neighbouring unirrigated, unfertilised, wintergrazed pasture. Primary terms in the NECB calculation were: net ecosystem production (NEP), biomass carbon removed by grazing cows and carbon (C) input from their excreta. Annual NEP was measured using the eddy-covariance method. Carbon removal was estimated with plate-meter measurements calibrated against biomass collections, preand post-grazing. Excreta deposition was calculated from animal feed intake. The intensively managed pasture gained C (NECB = 103 ± 42 g C m −2 yr −1 ) but would have been subject to a non-significant C loss if cattle excreta had not been returned to the pasture. The unirrigated pasture was C-neutral (NECB = −13 ± 23 g C m −2 yr −1 ). While annual GPP of the former was almost twice that of the latter (2679 vs. 1372 g C m −2 yr −1 ), ecosystem respiration differed by only 68 % between the two pastures (2271 vs. 1352 g C m −2 yr −1 ). The ratio of GPP to the total annual water input of the irrigated pasture was 37 % greater than that of the unirrigated pasture, i.e. the former used the water input more efficiently than the latter to produce biomass. The NECB results agree qualitatively with those from many other eddy-covariance studies of grazed grasslands, but they seem to be at odds with long-term carbon-stock studies of other New Zealand pastures.

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Section: J E Hunt Et Al: Carbon Budgets For An Irrigated and An Unmentioning

confidence: 77%

Carbon budgets for an irrigated intensively grazed dairy pasture and an unirrigated winter-grazed pasture

et al. 2016

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“…Studies on the closure problem of eddy covariance measurements highlight the landscape heterogeneity as a driving factor for the lack of closure (Stoy et al, 2013) but also stress the importance of measurement scales (Foken, 2008). Due to the striking small-scale heterogeneity of soil moisture availability and vegetation cover in Arctic landscapes, measurements of point-scale G and radiative components may not represent the large source area of eddy covariance H and LE.…”

Section: Energy Balance Closure and System Performancementioning

confidence: 99%

Two years with extreme and little snowfall: effects on energy partitioning and surface energy exchange in a high-Arctic tundra ecosystem

et al. 2016

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Abstract. Snow cover is one of the key factors controlling Arctic ecosystem functioning and productivity. In this study we assess the impact of strong variability in snow accumulation during 2 subsequent years (2013-2014) on the landatmosphere interactions and surface energy exchange in two high-Arctic tundra ecosystems (wet fen and dry heath) in Zackenberg, Northeast Greenland. We observed that recordlow snow cover during the winter 2012/2013 resulted in a strong response of the heath ecosystem towards low evaporative capacity and substantial surface heat loss by sensible heat fluxes (H ) during the subsequent snowmelt period and growing season. Above-average snow accumulation during the winter 2013/2014 promoted summertime ground heat fluxes (G) and latent heat fluxes (LE) at the cost of H . At the fen ecosystem a more muted response of LE, H and G was observed in response to the variability in snow accumulation. Overall, the differences in flux partitioning and in the length of the snowmelt periods and growing seasons during the 2 years had a strong impact on the total accumulation of the surface energy balance components. We suggest that in a changing climate with higher temperature and more precipitation the surface energy balance of this high-Arctic tundra ecosystem may experience a further increase in the variability of energy accumulation, partitioning and redistribution.

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“…Low EBCs (60-80 %) were mainly observed at various agricultural sites and bare soil, whereas over forest they were typically higher (80-90 %) (Charuchittipan et al, 2014;Wilson et al, 2002;Foken, 2008a;Panin and Bernhofer, 2008;Stoy et al, 2013). The imbalance usually occurs during day time, particularly around noon, whereas during the night when fluxes are low EBC is often close to unity (Oncley et al, 2007).…”

Section: K Imukova Et Al: Energy Balance Closure On a Winter Wheat mentioning

confidence: 99%

“…This conclusion is supported by Heusinkveld et al (2004); they found a perfect EBC over a homogeneous surface: a desert in Israel. Tsvang et al (1991) and Stoy et al (2013) also concluded that the heterogeneities of the surrounding area are an important factor contributing to the lack of EBC. Several authors (Klaassen and Sogachev, 2006;Friedrich et al, 2000) reported an increase of the turbulent fluxes at forest edges.…”

Section: K Imukova Et Al: Energy Balance Closure On a Winter Wheat mentioning

confidence: 99%

Energy balance closure on a winter wheat stand: comparing the eddy covariance technique with the soil water balance method

et al. 2016

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Abstract. The energy balance of eddy covariance (EC) flux data is typically not closed. The nature of the gap is usually not known, which hampers using EC data to parameterize and test models. In the present study we crosschecked the evapotranspiration data obtained with the EC method (ET EC ) against ET rates measured with the soil water balance method (ET WB ) at winter wheat stands in southwest Germany. During the growing seasons 2012 and 2013, we continuously measured, in a half-hourly resolution, latent heat (LE) and sensible (H ) heat fluxes using the EC technique. Measured fluxes were adjusted with either the Bowen-ratio (BR), H or LE post-closure method. ET WB was estimated based on rainfall, seepage and soil water storage measurements. The soil water storage term was determined at sixteen locations within the footprint of an EC station, by measuring the soil water content down to a soil depth of 1.5 m. In the second year, the volumetric soil water content was additionally continuously measured in 15 min resolution in 10 cm intervals down to 90 cm depth with sixteen capacitance soil moisture sensors. During the 2012 growing season, the H post-closed LE flux data (ET EC = 3.4 ± 0.6 mm day −1 ) corresponded closest with the result of the WB method (3.3 ± 0.3 mm day −1 ). ET EC adjusted by the BR (4.1 ± 0.6 mm day −1 ) or LE (4.9 ± 0.9 mm day −1 ) post-closure method were higher than the ET WB by 24 and 48 %, respectively. In 2013, ET WB was in best agreement with ET EC adjusted with the H postclosure method during the periods with low amount of rain and seepage. During these periods the BR and LE postclosure methods overestimated ET by about 46 and 70 %, respectively. During a period with high and frequent rainfalls, ET WB was in-between ET EC adjusted by H and BR post-closure methods. We conclude that, at most observation periods on our site, LE is not a major component of the energy balance gap. Our results indicate that the energy balance gap is made up by other energy fluxes and unconsidered or biased energy storage terms.

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A data-driven analysis of energy balance closure across FLUXNET research sites: The role of landscape scale heterogeneity

Cited by 500 publications

References 203 publications

Carbon budgets for an irrigated intensively grazed dairy pasture and an unirrigated winter-grazed pasture

Carbon budgets for an irrigated intensively grazed dairy pasture and an unirrigated winter-grazed pasture

Two years with extreme and little snowfall: effects on energy partitioning and surface energy exchange in a high-Arctic tundra ecosystem

Energy balance closure on a winter wheat stand: comparing the eddy covariance technique with the soil water balance method

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