Heterogeneity of competition at decameter scale: patches of high canopy leaf area in a shade-intolerant larch stand transpire less yet are more sensitive to drought

Xiong, Wei; Oren, Ram; Wang, Yanhui; Yu, Pengtao; Liu, Hailong; Cao, Gongxiang; Xu, Lihong; Wang, Yunni; Zuo, Haijun

doi:10.1093/treephys/tpv022

Research article2015Peer reviewedOpen access

Heterogeneity of competition at decameter scale: patches of high canopy leaf area in a shade-intolerant larch stand transpire less yet are more sensitive to drought

Xiong, Wei; Oren, Ram; Wang, Yanhui; Yu, Pengtao; Liu, Hailong; Cao, Gongxiang; Xu, Lihong; Wang, Yunni; Zuo, Haijun

Abstract

Small differences in the sensitivity of stomatal conductance to light intensity on leaf surfaces may lead to large differences in total canopy transpiration (E-C) with increasing canopy leaf area (L). Typically, the increase of L would more than compensate for the decrease of transpiration per unit of leaf area (E-L), resulting in concurrent increase of E-C. However, highly shade-intolerant species, such as Larix principis-rupprechtii Mayr., may be so sensitive to increased shading that such compensation is not complete. We hypothesized that in such a stand, windfall-induced spatial variation at a decameter scale would result in greatly reduced E-L in patches of high L leading to lower E-C than low competition patches of sparse canopy. We further hypothesized that quicker extraction of soil moisture in patches of lower competition will result in earlier onset of drought symptoms in these patches. Thus, patches of low L will transition from light to soil moisture as the factor dominating E-L. This process should progressively homogenize E-C in the stand even as the variation of soil moisture is increasing. We tested the hypotheses utilizing sap flux of nine trees, and associated environmental and stand variables. The results were consistent with only some of the expectations. Under non-limiting soil moisture, E-L was very sensitive to the spatial variation of L, decreasing sharply with increasing L and associated decrease of mean light intensity on leaf surfaces. Thus, under the conditions of ample soil moisture maximum E-C decreased with increasing patch-scale L. Annual E-C and biomass production also decreased with L, albeit more weakly. Furthermore, variation of E-C among patches decreased as average stand soil moisture declined between rain events. However, contrary to expectation, high L plots which transpired less showed a greater E-L sensitivity to decreasing stand-scale soil moisture, suggesting a different mechanism than simple control by decreasing soil moisture. We offer potential explanations to the observed phenomenon. Our results demonstrate that spatial variation of L at decameter scale, even within relatively homogeneous, single-species, even-aged stands, can produce large variation of transpiration, soil moisture and biomass production and should be considered in 1-D soil-plant-atmosphere models.

Keywords

light absorption; net primary production; soil moisture; soil water potential; spatiotemporal analysis; transpiration

Published in

Tree Physiology
2015, volume: 35, number: 5, pages: 470-484
Publisher: OXFORD UNIV PRESS

SLU Authors

Oren, Ram
- Department of Forest Ecology and Management, Swedish University of Agricultural Sciences

UKÄ Subject classification

Forest Science

Publication identifier

DOI: https://doi.org/10.1093/treephys/tpv022

Permanent link to this page (URI)

https://res.slu.se/id/publ/68507