EGU22-8620
https://doi.org/10.5194/egusphere-egu22-8620
EGU General Assembly 2022
© Author(s) 2022. This work is distributed under
the Creative Commons Attribution 4.0 License.

In situ monitoring of tree water uptake depths, storage and transport reveals different strategies during drought and recovery

Kathrin Kühnhammer1,2, Joost van Haren3, Angelika Kübert2, Maren Dubbert4, Nemiah Ladd2,5, Laura Meredith3, Christiane Werner2, and Matthias Beyer1
Kathrin Kühnhammer et al.
  • 1IGOE, Environmental Geochemistry, TU Braunschweig, Braunschweig, Germany (k.kuehnhammer@tu-braunschweig.de)
  • 2Ecosystem Physiology, University of Freiburg, Freiburg, Germany
  • 3Biosphere 2, Natural Resources & the Environment and Honors college, University of Arizona, USA
  • 4Isotope Biogeochemistry and Gasfluxes, ZALF, Müncheberg, Germany
  • 5Department of Environmental Sciences, University of Basel, Basel, Switzerland

Due to ongoing and likely intensifying climate change impacts, ecosystem water availability is altered across the globe. Humid tropical forests, which evolved under conditions of abundant water, might be particularly vulnerable to water stress. One important factor in a tree's resilience to a less reliable water supply from precipitation is a root system that reaches deep into the ground. However, accessing deep soil regions as well as observing active deep root water uptake is challenging. Consequently, the occurrence, functioning and importance of deep roots are not well understood.

The Biosphere 2 Tropical Rainforest in Arizona, USA offers a unique possibility to further investigate this knowledge gap as environmental conditions can be controlled and soil can be accessed from below. Within the interdisciplinary B2 WALD project, we imposed a two-month drought on the enclosed ecosystem. To identify deep water uptake, water labeled with 2H isotopes was supplied through a drainage system in 2-3 m soil depth before the drought ended. To investigate tree reactions to the manipulations in water supply, we closely monitored atmospheric conditions, soil water content and isotopic composition as well as tree sap flow, stem water content and the isotopic composition of tree xylem and transpired water. Only few data sets exist, combining water stable isotope information with different hydrometric measurements within the same experiment. Additionally, we used novel in situ approaches to monitor the isotopic composition in soils, tree xylem and transpiration in high temporal resolution.

Combining all measurements in 10 tree individuals of 5 different species, we found contrasting reactions to the added deep water. Except of two understory trees, all canopy trees had access to it, suggesting that deep roots could be a common feature also in tropical tree species. Trees did not use deep water in the same way. We observed differences in the speed and timing of the reaction as well as in within-tree water dynamics. While some individuals first refilled their stem water storage, others used the deep water source to preserve their sap flow and transpiration stream. This not only impacted the time course of tree water isotopes but knowledge of those different behaviors is pivotal in better understanding and predicting tree performance, survival and ecosystem water cycling. In summary, our data illustrates the need for an extensive network combining different measurements to correctly interpret tree water isotope dynamics, tree water use strategies and to further uncover the functioning of deep roots and assess their importance for ecosystem resilience in a changing climate.

How to cite: Kühnhammer, K., van Haren, J., Kübert, A., Dubbert, M., Ladd, N., Meredith, L., Werner, C., and Beyer, M.: In situ monitoring of tree water uptake depths, storage and transport reveals different strategies during drought and recovery, EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-8620, https://doi.org/10.5194/egusphere-egu22-8620, 2022.

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