Rainfall exclusion in an eastern Amazonian forest alters soil water movement and depth of water uptake

Deuterium-labeled water was used to study the effect of the Tapajós Throughfall Exclusion Experiment (TTEE) on soil moisture movement and on depth of water uptake by trees of Coussarea racemosa, Sclerolobium chrysophyllum, and Eschweilera pedicellata. The TTEE simulates an extended dry season in an...

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Veröffentlicht in:	American journal of botany 2005-03, Vol.92 (3), p.443-455
Hauptverfasser:	Romero-Saltos, Hugo, Sternberg, Leonel da S. L, Moreira, Marcelo Z, Nepstad, Daniel C
Format:	Artikel
Sprache:	eng
Schlagworte:	Caesalpinioideae climate change climatic factors Coussarea racemosa Deuterium deuterium oxide drought drought tolerance dry season Dry seasons eastern Amazonia El Niño Eschweilera Eschweilera pedicellata Forest soils global climate change Irrigation plant-water relations radiolabeling Rain Rainforests Rainy seasons Rubiaceae Sclerolobium chrysophyllum Soil depth Soil water soil water movement Soils Throughfall Trees Tropical Biology tropical rain forests unsaturated hydraulic conductivity Water depth Water measurement Water uptake
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creator	Romero-Saltos, Hugo Sternberg, Leonel da S. L Moreira, Marcelo Z Nepstad, Daniel C
description	Deuterium-labeled water was used to study the effect of the Tapajós Throughfall Exclusion Experiment (TTEE) on soil moisture movement and on depth of water uptake by trees of Coussarea racemosa, Sclerolobium chrysophyllum, and Eschweilera pedicellata. The TTEE simulates an extended dry season in an eastern Amazonian rainforest, a plausible scenario if the El Niño phenomenon changes with climate change. The TTEE excludes 60% of the wet season throughfall from a 1-ha plot (treatment), while the control 1-ha plot receives precipitation year-round. Mean percolation rate of the label peak in the control plot was greater than in the treatment plot during the wet season (0.75 vs. 0.07 m/mo). The rate was similar for both plots during the dry season (ca. 0.15 m/mo), indicative that both plots have similar topsoil structure. Interestingly, the label peak in the control plot during the dry season migrated upward an average distance of 64 cm. We show that water probably moved upward through soil pores--i.e., it did not involve roots (hydraulic lift)--most likely because of a favorable gradient of total (matric + gravitational) potential coupled with sufficient unsaturated hydraulic conductivity. Water probably also moved upward in the treatment plot, but was not detectable; the label in this plot did not percolate below 1 m or beyond the depth of plant water uptake. During the dry season, trees in the rainfall exclusion plot, regardless of species, consistently absorbed water significantly deeper, but never below 1.5-2 m, than trees in the control plot, and therefore may represent expected root function of this understory/subcanopy tree community during extended dry periods.
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L</creatorcontrib><creatorcontrib>Moreira, Marcelo Z</creatorcontrib><creatorcontrib>Nepstad, Daniel C</creatorcontrib><title>Rainfall exclusion in an eastern Amazonian forest alters soil water movement and depth of water uptake</title><title>American journal of botany</title><addtitle>Am J Bot</addtitle><description>Deuterium-labeled water was used to study the effect of the Tapajós Throughfall Exclusion Experiment (TTEE) on soil moisture movement and on depth of water uptake by trees of Coussarea racemosa, Sclerolobium chrysophyllum, and Eschweilera pedicellata. The TTEE simulates an extended dry season in an eastern Amazonian rainforest, a plausible scenario if the El Niño phenomenon changes with climate change. The TTEE excludes 60% of the wet season throughfall from a 1-ha plot (treatment), while the control 1-ha plot receives precipitation year-round. Mean percolation rate of the label peak in the control plot was greater than in the treatment plot during the wet season (0.75 vs. 0.07 m/mo). The rate was similar for both plots during the dry season (ca. 0.15 m/mo), indicative that both plots have similar topsoil structure. Interestingly, the label peak in the control plot during the dry season migrated upward an average distance of 64 cm. We show that water probably moved upward through soil pores--i.e., it did not involve roots (hydraulic lift)--most likely because of a favorable gradient of total (matric + gravitational) potential coupled with sufficient unsaturated hydraulic conductivity. Water probably also moved upward in the treatment plot, but was not detectable; the label in this plot did not percolate below 1 m or beyond the depth of plant water uptake. During the dry season, trees in the rainfall exclusion plot, regardless of species, consistently absorbed water significantly deeper, but never below 1.5-2 m, than trees in the control plot, and therefore may represent expected root function of this understory/subcanopy tree community during extended dry periods.</description><subject>Caesalpinioideae</subject><subject>climate change</subject><subject>climatic factors</subject><subject>Coussarea racemosa</subject><subject>Deuterium</subject><subject>deuterium oxide</subject><subject>drought</subject><subject>drought tolerance</subject><subject>dry season</subject><subject>Dry seasons</subject><subject>eastern Amazonia</subject><subject>El Niño</subject><subject>Eschweilera</subject><subject>Eschweilera pedicellata</subject><subject>Forest soils</subject><subject>global climate change</subject><subject>Irrigation</subject><subject>plant-water relations</subject><subject>radiolabeling</subject><subject>Rain</subject><subject>Rainforests</subject><subject>Rainy seasons</subject><subject>Rubiaceae</subject><subject>Sclerolobium chrysophyllum</subject><subject>Soil depth</subject><subject>Soil water</subject><subject>soil water movement</subject><subject>Soils</subject><subject>Throughfall</subject><subject>Trees</subject><subject>Tropical Biology</subject><subject>tropical rain forests</subject><subject>unsaturated hydraulic conductivity</subject><subject>Water depth</subject><subject>Water measurement</subject><subject>Water uptake</subject><issn>0002-9122</issn><issn>1537-2197</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2005</creationdate><recordtype>article</recordtype><recordid>eNp9kk1v1DAQhi0EokvhxhGBhVS4kMUex0l8XCo-VQkJytlyErvrJYm3dkJafj1TZakQh55szzzzesavCXnK2VqUAt6aXb1WsBbrPBf3yIpLUWbAVXmfrBhjkCkOcEQepbTDo8oVPCRHwAsJOfAVcd-MH5zpOmqvmm5KPgzUD9QM1Jo02jjQTW9-h8FjxIVo00hNh_FEU_AdnQ3uaR9-2d4OmBpa2tr9uKXBHXLTfjQ_7WPyAC9J9slhPSbnH96fn37Kzr5-_Hy6OcsaKUBkFS-h4K7IRdGqvFZFW5aili0wxwtrQJaqZkpUZeUYtt-4HGxrZCulAVZYcUxeL7L7GC4nbFb3PjW268xgw5R0VXJR5QASyVd3krwUvBBMIPjyP3AXpjjgEBq4rKqikDdqbxaoiSGlaJ3eR9-beK050zcuaXRJK9BCo0uIPz9oTnVv21v4ry0IwALMvrPXd4rpzZd3wBbVZ0vRLo0h3hblHESlANMnS3rrL7azj1anHn3HFrie5_mf5l4snDNBm4vok_7xHRgX-HtwXHz-P9o3u1c</recordid><startdate>200503</startdate><enddate>200503</enddate><creator>Romero-Saltos, Hugo</creator><creator>Sternberg, Leonel da S. 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L</au><au>Moreira, Marcelo Z</au><au>Nepstad, Daniel C</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Rainfall exclusion in an eastern Amazonian forest alters soil water movement and depth of water uptake</atitle><jtitle>American journal of botany</jtitle><addtitle>Am J Bot</addtitle><date>2005-03</date><risdate>2005</risdate><volume>92</volume><issue>3</issue><spage>443</spage><epage>455</epage><pages>443-455</pages><issn>0002-9122</issn><eissn>1537-2197</eissn><coden>AJBOAA</coden><abstract>Deuterium-labeled water was used to study the effect of the Tapajós Throughfall Exclusion Experiment (TTEE) on soil moisture movement and on depth of water uptake by trees of Coussarea racemosa, Sclerolobium chrysophyllum, and Eschweilera pedicellata. The TTEE simulates an extended dry season in an eastern Amazonian rainforest, a plausible scenario if the El Niño phenomenon changes with climate change. The TTEE excludes 60% of the wet season throughfall from a 1-ha plot (treatment), while the control 1-ha plot receives precipitation year-round. Mean percolation rate of the label peak in the control plot was greater than in the treatment plot during the wet season (0.75 vs. 0.07 m/mo). The rate was similar for both plots during the dry season (ca. 0.15 m/mo), indicative that both plots have similar topsoil structure. Interestingly, the label peak in the control plot during the dry season migrated upward an average distance of 64 cm. We show that water probably moved upward through soil pores--i.e., it did not involve roots (hydraulic lift)--most likely because of a favorable gradient of total (matric + gravitational) potential coupled with sufficient unsaturated hydraulic conductivity. Water probably also moved upward in the treatment plot, but was not detectable; the label in this plot did not percolate below 1 m or beyond the depth of plant water uptake. During the dry season, trees in the rainfall exclusion plot, regardless of species, consistently absorbed water significantly deeper, but never below 1.5-2 m, than trees in the control plot, and therefore may represent expected root function of this understory/subcanopy tree community during extended dry periods.</abstract><cop>United States</cop><pub>Botanical Soc America</pub><pmid>21652421</pmid><doi>10.3732/ajb.92.3.443</doi><tpages>13</tpages></addata></record>
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subjects	Caesalpinioideae climate change climatic factors Coussarea racemosa Deuterium deuterium oxide drought drought tolerance dry season Dry seasons eastern Amazonia El Niño Eschweilera Eschweilera pedicellata Forest soils global climate change Irrigation plant-water relations radiolabeling Rain Rainforests Rainy seasons Rubiaceae Sclerolobium chrysophyllum Soil depth Soil water soil water movement Soils Throughfall Trees Tropical Biology tropical rain forests unsaturated hydraulic conductivity Water depth Water measurement Water uptake
title	Rainfall exclusion in an eastern Amazonian forest alters soil water movement and depth of water uptake
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