Use of temporal patterns in vapor pressure deficit to explain spatial autocorrelation dynamics in tree transpiration

doi:10.1093/treephys/28.4.647

Tree Physiology 2008 28(4):647-658; doi:10.1093/treephys/28.4.647

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Use of temporal patterns in vapor pressure deficit to explain spatial autocorrelation dynamics in tree transpiration

Jonathan D. Adelman¹, Brent E. Ewers¹^,2 and D. Scott MacKay³

¹ Department of Botany, University of Wyoming Laramie, WY 82071, USA
² Corresponding author beewers{at}uwyo.edu
³ Department of Geography, State University of New York Buffalo, NY, USA

Abstract

To quantify the relationship between temporal and spatial variationin tree transpiration, we measured sap flow in 129 trees withconstant-heat sap flow sensors in a subalpine forest in southernWyoming, USA. The forest stand was located along a soil watergradient from a stream side to near the top of a ridge. Thestand was dominated by Pinus contorta Dougl. ex Loud. with Piceaengelmannii Parry ex Engelm and Abies lasiocarpa (Hook.) Nutt.present near the stream and scattered individuals of Populustremuloides Michx. throughout the stand. We used a cyclic samplingdesign that maximized spatial information with a minimum numberof samples for semivariogram analyses. All species exhibitedpreviously established responses to environmental variablesin which the dominant driver was a saturating response to vaporpressure deficit (D). This response to D is predictable fromtree hydraulic theory in which stomatal conductance declinesas D increases to prevent excessive cavitation. The degree towhich stomatal conductance declines with D is dependent on bothspecies and individual tree physiology and increases the variabilityin transpiration as D increases. We quantified this variabilityspatially by calculating the spatial autocorrelation within0.2-kPa D bins. Across 11 bins of D, spatial autocorrelationin individual tree transpiration was inversely correlated toD and dropped from 45 to 20 m. Spatial autocorrelation was muchless for transpiration per unit leaf area and not significantfor transpiration per unit sapwood area suggesting that spatialautocorrelation within a particular D bin could be explainedby tree size. Future research should focus on the mechanismsunderlying tree size spatial variability, and the potentiallybroad applicability of the inverse relationship between D andspatial autocorrelation in tree transpiration.

Keywords: geostatistics, sapwood area, scaling, tree hydraulics

Received May 3, 2007; Accepted June 18, 2007

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