Trees never rest: the multiple facets of hydraulic redistribution

Nadezhdina, Nadezhda; David, Teresa S.; David, Jorge S.; Ferreira, Maria Isabel; Dohnal, Michal; Tesař, Miroslav; Gartner, Karl; Leitgeb, Ernst; Nadezhdin, Valeriy; Čermák, Jan; Jiménez, María Soledad; Morales, D.

doi:10.1002/eco.148

Cited by 136 publications

(109 citation statements)

References 48 publications

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“…Recent research utilizing data from Liz experimental catchment included studies on evapotranspiration (Pražák et al, 1996), cloud and fog water deposition (Eliáš et al, 1995), water regime affected by vegetation cover changes (Buchtele et al, 2006), hydraulic redistribution of water by roots (Nadezhdina et al, 2010), development and testing of macroscopic root water uptake model (Vogel et al, 2013), and predictions of heat fluxes in structured soil profile (Votrubová et al, 2012).…”

Section: Materials and Methods Experimental Areamentioning

confidence: 99%

Rainfall interception and spatial variability of throughfall in spruce stand

Dohnal

Cerny

Votrubová

et al. 2014

Journal of Hydrology and Hydromechanics

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Abstract:The interception was recognized as an important part of the catchment water balance in temperate climate. The mountainous forest ecosystem at experimental headwater catchment Liz has been subject of long-term monitoring. Unique dataset in terms of time resolution serves to determine canopy storage capacity and free throughfall. Spatial variability of throughfall was studied using one weighing and five tipping bucket rain gauges. The basic characteristics of forest affecting interception process were determined for the Norway spruce stand at the experimental area -the leaf area index was 5.66 -6.00 m 2 m -2 , the basal area was 55.7 m 2 ha -1 , and the crown closure above individual rain gauges was between 19 and 95%. The total interception loss in both growing seasons analyzed was 34.5%. The mean value of the interception capacity determined was about 2 mm. Throughfall exhibited high variability from place to place and it was strongly affected by character of rainfall. On the other hand, spatial pattern of throughfall in average showed low variability.

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Section: Materials and Methods Experimental Areamentioning

confidence: 99%

Rainfall interception and spatial variability of throughfall in spruce stand

Dohnal

Cerny

Votrubová

et al. 2014

Journal of Hydrology and Hydromechanics

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“…We propose the hypothesis that the presence of forests in large basins is determinant for the occurrence of a given partitioning pattern, mainly because forests have a strong potential to modify the 10 components of the surface water balance. There is a variety of mechanisms through which forests can exert strong effects on the components of long-term water balance in river basins These factors include, but are not limited to: accumulation and redistribution of soil moisture by root systems (Nadezhdina et al, 2010;Nepstad et al, 1994;Lee et al, 2005;Bond et al, 2002), strong capacity for stomatal regulation related to the large cumulative surface area of leaves (Berry et al, 2010;Costa and Foley, 1997;Katul et al, 2012), physiological adaptations for water and light use efficiency (Nadezhdina et al, 2010), 15 landscape-scale energy balance effects and overall dynamics of E (Villegas et al, 2014), land-atmosphere interactions that enhance the capacity of river basins to store water as a natural "reservoir" (Salazar et al, 2017), activation of shallow convection through transpiration (Wright et al, 2017), below-canopy stability that restricts direct soil evaporation (Henao et al, Submitted), and soil moisture control via canopy effects on hydrological partitioning (Fleischbein et al, 2005). Collectively, these mechanisms define biophysical relations between the presence of forests and the dynamics of P , E and R, and imply a 20 strong potential of forests for modifying the long-term patterns of water balance partitioning.…”

Section: The Role Of Forestsmentioning

confidence: 99%

Global synthesis of forest cover effects on long-term water balance partitioning in large basins

Mercado‐Bettín

Salazar

Villegas

2017

Preprint

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Abstract. Global changes in forest cover have been related to major scientific and social challenges. There are important uncertainties about the potential effects of ongoing forest loss on continental water balances. Here we present an observationbased analysis of long-term water balance partitioning (precipitation divided into evaporation and runoff) in 22 large basins of the world, whereby we identify two partitioning patterns likely related to biophysical mechanisms that depend on the presence and abundance of forests. In less forested basins, evaporation dominates water balance and, as forest cover increases, 5 this dominance of evaporation over runoff is reduced. When forest is the predominant cover, both components account for nearly half of precipitation in the long-term water balance. The distinction between these two patterns is not fully explained by differences between water-and energy-limited environments, but requires consideration of other biophysical properties that affect precipitation and its conversion into evaporation and runoff. Our results indicate that forest cover is an effective descriptor of basin attributes that are relevant for characterizing long-term water balance partitioning in large basins of the world. Further, 10 our results provide insights to understanding and predicting the potential consequences of forest loss on continental water availability, a critical determinant for multiple ecological and societal processes.

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“…In general, the relationship between SF and transpiration is linear, and can be used for the calculation of tree transpiration (Clausnitzer et al 2011). Sap flow and transpiration are closely correlated not only to meteorological factors, such as vapour pressure deficit and potential evapotranspiration (Dragoni et al 2009;Köhler et al 2010), but also to soil water content and physiological parameters (Nadezhdina at al. 2010;Dalsgaard et al 2011;Klein at al.…”

Section: Introductionmentioning

confidence: 99%

Differences in transpiration of Norway spruce drought stressed trees and trees well supplied with water

et al. 2013

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The paper focuses on the evaluation of transpiration as a physiological process, which is very sensitive to drought stress. Reactions of 25-year-old Norway spruce (Picea abies (L.) Karst.) trees to drought were examined during 2009 summer. Sap flow rate (SF), meteorological and soil characteristics were measured continually. Vapour pressure deficit of the air (VPD) and cumulative transpiration deficit (KTD) was calculated. During the second half of the vegetation period, the decrease in soil water content was observed and irrigation was applied to a group of spruce trees, while the second group was treated under natural soil drought. On the days, when the differences in transpiration between irrigated (IR) and non-irrigated (NIR) trees were significant (21 days), transpiration of NIR trees was only 23% of the transpiration of IR trees. We found significant differences in transpiration when the soil water content (SWC) of NIR variant at a depth of 5-15 cm ranged from 10.4 to 13.7%. Under both regimes of water availability, daily transpiration significantly responded to atmospheric conditions. However, the influence of all assessed meteorological parameters on SF of NIR trees was significantly lower than on IR tree. The dependency of transpiration on evaporative demands of atmosphere decreased with the decreasing soil moisture. Cumulative transpiration deficit of the stand during the entire evaluated period was 50.9 mm. The difference between the transpiration of the mean NIR tree and of the mean IR tree was 278.8 L over the assessed period of 47 days (5.9 L per day). The transpiration of NIR trees was 40.3% from the transpiration of IR trees during this period.

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Trees never rest: the multiple facets of hydraulic redistribution

Cited by 136 publications

References 48 publications

Rainfall interception and spatial variability of throughfall in spruce stand

Rainfall interception and spatial variability of throughfall in spruce stand

Global synthesis of forest cover effects on long-term water balance partitioning in large basins

Differences in transpiration of Norway spruce drought stressed trees and trees well supplied with water

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