Footprint prediction of scalar fluxes from analytical solutions of the diffusion equation

Schuepp, P. H.; Leclerc, Monique Y.; MacPherson, J. I.; Desjardins, Raymond L.

doi:10.1007/bf00120530

Cited by 749 publications

(426 citation statements)

References 27 publications

(52 reference statements)

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“…Although the Schmid [1997] model yields similar values for the point of maximum contribution as the Schuepp et al [1990] model, the assumptions for the trailing end of the footprint and thus for the potential contribution of the land surface to fluxes measured over the lake are not identical. Schmid [2002] provides a thorough review of various footprint calculations and addresses their limitations and weaknesses.…”

Section: Aclmentioning

confidence: 99%

CO₂ exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

et al. 2003

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[1] CO 2 exchange between lake water and the atmosphere was investigated at Toolik Lake (Alaska) and Soppensee (Switzerland) employing the eddy covariance (EC) method. The results obtained from three field campaigns at the two sites indicate the importance of convection in the lake in driving gas flux across the water-air interface. Measurements were performed during short (1-3 day) periods with observed diurnal changes between stratified and convective conditions in the lakes. Over Toolik Lake the EC net CO 2 efflux was 114 ± 33 mg C m À2 d À1 , which compares well with the 131 ± 2 mg C m À2 d À1 estimated by a boundary layer model (BLM) and the 153 ± 3 mg C m À2 d À1 obtained with a surface renewal model (SRM). Floating chamber measurements, however, indicated a net efflux of 365 ± 61 mg C m À2 d À1 , which is more than double the EC fluxes measured at the corresponding times (150 ± 78 mg C m À2 d À1 ). The differences between continous (EC, SRM, and BLM) and episodic (chamber) flux determination indicate that the chamber measurements might be biased depending on the chosen sampling interval. Significantly smaller fluxes ( p < 0.06) were found during stratified periods (51 ± 42 mg C m À2 d À1 ) than were found during convective periods (150 ± 45 mg C m À2 d À1 ) by the EC method, but not by the BLM. However, the congruence between average values obtained by the models and EC supports the use of both methods, but EC measurements and the SRM provide more insight into the physical-biological processes affecting gas flux. Over Soppensee, the daily net efflux from the lake was 289 ± 153 mg C m À2 d À1 during the measuring period. Flux differences were significant ( p < 0.002) between stratified periods (240 ± 82 mg C m À2 d À1 ) and periods with penetrative convection (1117 ± 236 mg C m À2 d À1 ) but insignificant if convection in the lake was weak and nonpenetrative. Our data indicate the importance of periods of heat loss and convective mixing to the process of gas exchange across the water surface, and calculations of gas transfer velocity using the surface renewal model support our observations. Future studies should employ the EC method in order to obtain essential data for process-scale investigations. Measurements should be extended to cover the full season from thaw to freeze, thereby integrating data over stratified and convective periods. Thus the statistical confidence in the seasonal budgets of CO 2 and other trace gases that are exchanged across lake surfaces could be increased considerably.

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Section: Aclmentioning

confidence: 99%

CO₂ exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

et al. 2003

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“…The size of this footprint is mainly dependent on a combination of atmospheric stability, surface roughness, as well as the measurement height. We analyzed the footprint according to the model presented by Schuepp et al (1990) and used a distance within which 80 % of the measured flux value originates. This distance in our EC setup for the daytime conditions ranged *300 m and for nighttime up to 400-500 m. The mire has a very stable and well-defined easterly-westerly wind direction distribution (95 % of winds are evenly distributed along the Lake Torneträsk Valley) and very rarely winds from north and south.…”

Section: Site Descriptionmentioning

confidence: 99%

Monitoring the Multi-Year Carbon Balance of a Subarctic Palsa Mire with Micrometeorological Techniques

Christensen

Jackowicz-Korczyński

Aurela

et al. 2012

AMBIO

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This article reports a dataset on 8 years of monitoring carbon fluxes in a subarctic palsa mire based on micrometeorological eddy covariance measurements. The mire is a complex with wet minerotrophic areas and elevated dry palsa as well as intermediate sub-ecosystems. The measurements document primarily the emission originating from the wet parts of the mire dominated by a rather homogenous cover of Eriophorum angustifolium. The CO 2 /CH 4 flux measurements performed during the years [2001][2002][2003][2004][2005][2006][2007][2008] showed that the areas represented in the measurements were a relatively stable sink of carbon with an average annual rate of uptake amounting to on average -46 g C m -2 y -1 including an equally stable loss through CH 4 emissions (18-22 g CH 4 -C m -2 y -1 ). This consistent carbon sink combined with substantial CH 4 emissions is most likely what is to be expected as the permafrost under palsa mires degrades in response to climate warming.

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“…These differences maybe due to differences in sampling location and spatial averam@nng (Hope et a)., 1995). For example, eddy correlation flux measurements were taken from a height of 2.5 m, which, depending on the wind speed and temperature profile, corresponds to sampling area that is at least 4 orders of magnitude greater than the chamber sampling area (Schuepp et al 1990 1995;Oechef and1995). Hummock ecosystems at the former IBP Tareya site on the Tiiymyr Peninsula were small net sources of approximately 0.25 gC m-* d-1, while wetter polygonal ecosystems were slight sinks of 0.13 gC m-2 d-1.…”

Section: -mentioning

confidence: 99%

Response of a tundra ecosytem to elevated atmospheric carbon dioxide and CO{sub 2}-induced climate change. Final report

Oechel¹

1996

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Footprint prediction of scalar fluxes from analytical solutions of the diffusion equation

Cited by 749 publications

References 27 publications

CO₂ exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

CO₂ exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

Monitoring the Multi-Year Carbon Balance of a Subarctic Palsa Mire with Micrometeorological Techniques

Response of a tundra ecosytem to elevated atmospheric carbon dioxide and CO{sub 2}-induced climate change. Final report

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Footprint prediction of scalar fluxes from analytical solutions of the diffusion equation

Cited by 749 publications

References 27 publications

CO2 exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

CO2 exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

Monitoring the Multi-Year Carbon Balance of a Subarctic Palsa Mire with Micrometeorological Techniques

Response of a tundra ecosytem to elevated atmospheric carbon dioxide and CO{sub 2}-induced climate change. Final report

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CO₂ exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing

CO₂ exchange between air and water in an Arctic Alaskan and midlatitude Swiss lake: Importance of convective mixing