Artigo

The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia

The landscape of central Amazonia is composed of plateaus and valleys. Previous observations have shown preferential pooling of CO2 in the valleys, suggesting that the change in CO2 storage in the canopy air space (S) will be spatially variable at the scale of the topography. This may affect the int...

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Autor principal: Araüjo, Alessandro Carioca de
Outros Autores: Dolman, A. Johannes, Waterloo, M. J., Gash, John H.C., Kruijt, Bart J., Zanchi, Fabrício Berton, Lange, J. M.E. de, Stoevelaar, Rob, Manzi, Antônio Ocimar, Nobre, Antônio Donato, Lootens, R. N., Backer, J.
Grau: Artigo
Idioma: English
Publicado em: Agricultural and Forest Meteorology 2020
Assuntos:
Canopy Exchange
Carbon Balance
Carbon Dioxide
Carbon Flux
Carbon Sequestration
Complex Terrain
Eddy Covariance
Micrometeorology
Net Ecosystem Exchange
Respiration
Seasonal Variation
Spatial Variation
Topographic Effect
Vertical Profile
Amazonia
Acesso em linha: https://repositorio.inpa.gov.br/handle/1/18346
id oai:repositorio:1-18346
recordtype dspace
spelling oai:repositorio:1-18346 The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia Araüjo, Alessandro Carioca de Dolman, A. Johannes Waterloo, M. J. Gash, John H.C. Kruijt, Bart J. Zanchi, Fabrício Berton Lange, J. M.E. de Stoevelaar, Rob Manzi, Antônio Ocimar Nobre, Antônio Donato Lootens, R. N. Backer, J. Canopy Exchange Carbon Balance Carbon Dioxide Carbon Flux Carbon Sequestration Complex Terrain Eddy Covariance Micrometeorology Net Ecosystem Exchange Respiration Seasonal Variation Spatial Variation Topographic Effect Vertical Profile Amazonia The landscape of central Amazonia is composed of plateaus and valleys. Previous observations have shown preferential pooling of CO2 in the valleys, suggesting that the change in CO2 storage in the canopy air space (S) will be spatially variable at the scale of the topography. This may affect the interpretation of the net ecosystem CO2 exchange (NEE) rates measured on the plateaus if they have used one single atmospheric CO2 concentration ([CO2]) vertical profile measurement system. We have measured the diel, spatial and seasonal variation of S along the topography by using a set of automated [CO2] vertical profile measurement systems. In addition, NEE, the above-canopy turbulent exchange of CO2 (Fc) and meteorological variables were also measured on a micrometeorological tower located on the plateau. The nocturnal accumulation of CO2 was larger on the slopes and in the valleys than on the plateau and was larger in the dry period than in the wet period. In addition, the release of this CO2 occurred later in the day on the slopes and in the valleys than on the plateau. Differences in the flow regime above the canopy along the topographical gradient, lateral drainage of respired CO2 downslope, and temporal, spatial, and seasonal variation of soil CO2 efflux (Rsoil) are thought to have contributed to this. These conditions cause S to be higher in magnitude on the slopes and in the valleys than on the plateau during midmorning hours. We demonstrate that there is a larger underestimation of Reco by nighttime eddy covariance (EC) measurements in the dry period than in the wet period. In addition, Reco - as derived from measurements only on the plateau (Fc + SP) - does not agree with that derived by an independent method. Yet S fluxes peaked at about 18:00-20:00 on the slopes and in the valleys, following a continuous decrease after this period until reaching a minimum just after dawn. NEE derived from Fc measured on the plateau and S measured on the plateau, slope and valley increased the estimates of Reco on the plateau by about 30% and 70% in the wet and dry periods, respectively. Particularly for flux-tower sites over complex terrain, we recommend measuring the spatial variability of CO2 at, at least two, more points along the topography to determine to what extent horizontal gradients and storage changes may contribute to tower fluxes. Finally, for sites that present topographical characteristics similar to that described in this study, care must be taken with the use of single in-canopy profiles of [CO2] to correct EC fluxes. © 2009 Elsevier B.V. All rights reserved. 2020-06-15T21:53:57Z 2020-06-15T21:53:57Z 2010 Artigo https://repositorio.inpa.gov.br/handle/1/18346 10.1016/j.agrformet.2009.11.005 en Volume 150, Número 2, Pags. 226-237 Restrito Agricultural and Forest Meteorology
institution Instituto Nacional de Pesquisas da Amazônia - Repositório Institucional
collection INPA-RI
language English
topic Canopy Exchange
Carbon Balance
Carbon Dioxide
Carbon Flux
Carbon Sequestration
Complex Terrain
Eddy Covariance
Micrometeorology
Net Ecosystem Exchange
Respiration
Seasonal Variation
Spatial Variation
Topographic Effect
Vertical Profile
Amazonia
spellingShingle Canopy Exchange
Carbon Balance
Carbon Dioxide
Carbon Flux
Carbon Sequestration
Complex Terrain
Eddy Covariance
Micrometeorology
Net Ecosystem Exchange
Respiration
Seasonal Variation
Spatial Variation
Topographic Effect
Vertical Profile
Amazonia
Araüjo, Alessandro Carioca de
The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia
topic_facet Canopy Exchange
Carbon Balance
Carbon Dioxide
Carbon Flux
Carbon Sequestration
Complex Terrain
Eddy Covariance
Micrometeorology
Net Ecosystem Exchange
Respiration
Seasonal Variation
Spatial Variation
Topographic Effect
Vertical Profile
Amazonia
description The landscape of central Amazonia is composed of plateaus and valleys. Previous observations have shown preferential pooling of CO2 in the valleys, suggesting that the change in CO2 storage in the canopy air space (S) will be spatially variable at the scale of the topography. This may affect the interpretation of the net ecosystem CO2 exchange (NEE) rates measured on the plateaus if they have used one single atmospheric CO2 concentration ([CO2]) vertical profile measurement system. We have measured the diel, spatial and seasonal variation of S along the topography by using a set of automated [CO2] vertical profile measurement systems. In addition, NEE, the above-canopy turbulent exchange of CO2 (Fc) and meteorological variables were also measured on a micrometeorological tower located on the plateau. The nocturnal accumulation of CO2 was larger on the slopes and in the valleys than on the plateau and was larger in the dry period than in the wet period. In addition, the release of this CO2 occurred later in the day on the slopes and in the valleys than on the plateau. Differences in the flow regime above the canopy along the topographical gradient, lateral drainage of respired CO2 downslope, and temporal, spatial, and seasonal variation of soil CO2 efflux (Rsoil) are thought to have contributed to this. These conditions cause S to be higher in magnitude on the slopes and in the valleys than on the plateau during midmorning hours. We demonstrate that there is a larger underestimation of Reco by nighttime eddy covariance (EC) measurements in the dry period than in the wet period. In addition, Reco - as derived from measurements only on the plateau (Fc + SP) - does not agree with that derived by an independent method. Yet S fluxes peaked at about 18:00-20:00 on the slopes and in the valleys, following a continuous decrease after this period until reaching a minimum just after dawn. NEE derived from Fc measured on the plateau and S measured on the plateau, slope and valley increased the estimates of Reco on the plateau by about 30% and 70% in the wet and dry periods, respectively. Particularly for flux-tower sites over complex terrain, we recommend measuring the spatial variability of CO2 at, at least two, more points along the topography to determine to what extent horizontal gradients and storage changes may contribute to tower fluxes. Finally, for sites that present topographical characteristics similar to that described in this study, care must be taken with the use of single in-canopy profiles of [CO2] to correct EC fluxes. © 2009 Elsevier B.V. All rights reserved.
format Artigo
author Araüjo, Alessandro Carioca de
author2 Dolman, A. Johannes
Waterloo, M. J.
Gash, John H.C.
Kruijt, Bart J.
Zanchi, Fabrício Berton
Lange, J. M.E. de
Stoevelaar, Rob
Manzi, Antônio Ocimar
Nobre, Antônio Donato
Lootens, R. N.
Backer, J.
author2Str Dolman, A. Johannes
Waterloo, M. J.
Gash, John H.C.
Kruijt, Bart J.
Zanchi, Fabrício Berton
Lange, J. M.E. de
Stoevelaar, Rob
Manzi, Antônio Ocimar
Nobre, Antônio Donato
Lootens, R. N.
Backer, J.
title The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia
title_short The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia
title_full The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia
title_fullStr The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia
title_full_unstemmed The spatial variability of CO2 storage and the interpretation of eddy covariance fluxes in central Amazonia
title_sort spatial variability of co2 storage and the interpretation of eddy covariance fluxes in central amazonia
publisher Agricultural and Forest Meteorology
publishDate 2020
url https://repositorio.inpa.gov.br/handle/1/18346
_version_ 1787142434728181760
score 11.755432

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