Abstract
We used the eddy covariance technique from July 2000 to July 2001 to measure the fluxes of sensible heat, water vapor, and CO2 between an old‐growth tropical forest in eastern Amazonia and the atmosphere. Precipitation varied seasonally, with a wet season from mid‐December 2000 to July 2001 characterized by successive rainy days, wet soil, and, relative to the dry season, cooler temperatures, greater cloudiness, and reduced incoming solar and net radiation. Average evapotranspiration decreased from 3.96 ± 0.65 mm/d during the dry season to 3.18 ± 0.76 mm/d during the wet season, in parallel with decreasing radiation and decreasing water vapor deficit. The average Bowen ratio was 0.17 ± 0.10, indicating that most of the incoming radiation was used for evaporation. The Bowen ratio was relatively low during the early wet season (December–March), as a result of increased evaporative fraction and reduced sensible heat flux. The seasonal decline in Bowen ratio and increase in evaporative fraction coincided with an increase in ecosystem CO2 assimilation capacity, which we attribute to the growth of new leaves. The evaporative fraction did not decline as the dry season progressed, implying that the forest did not become drought stressed. The roots extracted water throughout the top 250 cm of soil, and water redistribution, possibly by hydraulic lift, partially recharged the shallow soil during dry season nights. The lack of drought stress during the dry season was likely a consequence of deep rooting, and possibly vertical water movement, which allowed the trees to maintain access to soil water year round.
Highlights
Tropical forests play a key role in the hydrology of Amazonia
We focus on the diel and seasonal patterns of evapotranspiration, sensible heat flux, microclimate, and soil moisture observed from July 2000 to July 2001
In subsequent analyses we refer to the period 15 July to 14 December as the dry season and to the remaining period as the wet season
Summary
Tropical forests play a key role in the hydrology of Amazonia. About half of the moisture that falls in the Amazon basin originates from evapotranspiration off upwind forest, and the other half originates from evaporation off the tropical Atlantic Ocean (Nobre et al 1991). The regional pattern of precipitation within Amazonia is linked to the large-scale pattern of landsurface evaporation. The distribution of forest in the tropics is linked to rainfall, with closedcanopy evergreen forest occurring in areas with at least 2 m annual rainfall (Walter 1984). One of the goals of the Large-scale Biosphere-Atmosphere Experiment in Amazonia (LBA) is an improved understanding of the components that determine this coupling, including the Manuscriptreceived 8 January2002; accepted 10 June 2002; final version received 28 February2003. For reprintsof this Special Issue, see footnote 1, p.
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