Water use complementarity in old-growth mixed forests versus competition in younger successional mixed forests

Huang R, Meier WJH, Bräuning A, Fu P, Fan Z, Aryal S, Arsalani M, Zhu H, Xu C, Liang E, Sigdel SR, Grießinger J (2026)

Publication Type: Journal article

Publication year: 2026

Journal

Agricultural and Forest Meteorology Elsevier Masson

Book Volume: 386

Article Number: 111226

DOI: 10.1016/j.agrformet.2026.111226

Abstract

Water use strategies among coexisting species across successional gradients critically influence forest climate resilience and biodiversity conservation, but remain poorly understood for high-elevation regions. We investigated water use patterns of co-occurring species at three sites on the southeastern Tibetan Plateau and the eastern Himalayas using tree-ring oxygen isotopes (δ¹⁸OTR), isotope-enabled model outputs (LMDZ4iso), and Roden-model-based mechanistic simulations. Statistical comparisons using Steiger's Z-tests and bootstrap resampling reveal clear temporal partitioning among species at the old-growth sites (Wache and Baima) and substantial overlap at the younger successional site (Xincuo). Specifically, at Wache, Larix griffithii predominantly used August-October soil moisture (September peak), whereas Picea spinulosa accessed July-October soil water (August peak). At Baima, Larix potaninii utilized July-October soil moisture with September peak uptake, while Abies georgei accessed June-October soil water peaking in July. Conversely, at the Xincuo site, species in the younger successional forest, including Abies georgei and Hippophae tibetana, exhibited significant water use overlap from June to September (July peak). Simulations based on the Roden framework indicate that physiological processes, including stomatal and biochemical fractionation, explain 92.1 %–99.8 % of the observed interspecific δ¹⁸OTR offset (∼3 ‰). Nevertheless, δ¹⁸OTR chronologies still reliably capture interspecific differences in the seasonal timing of source-water uptake. Moreover, A. georgei acts as a flexible “bridge species,” shifting from temporally partitioned water use in old-growth forests to overlapping resource use at the younger site, where shallow soils likely constrain niche differentiation. These results suggest that forest succession may enhance niche complementarity by increasing effective soil-water niche space. Such shifts in resource partitioning may play an important role in maintaining forest resilience under projected regional warming and precipitation change. Integrating δ¹⁸OTR observations with isotope-enabled model outputs and mechanistic simulations provides a useful framework for investigating species-level ecohydrological strategies in alpine forests.

Authors with CRIS profile

Achim Bräuning Lehrstuhl für Geographie (Physische Geographie) Sugam Aryal Lehrstuhl für Geographie (Physische Geographie) Mohsen Arsalani Institut für Geographie

Involved external institutions

Chinese Academy of Sciences (CAS) / 中国科学院

China (CN) Universität Salzburg (Paris Lodron Universität Salzburg)

Austria (AT) Xishuangbanna Tropical Botanical Garden (XTBG)

China (CN) Institute of Geology and Geophysics, Chinese Academy of Sciences

China (CN)

How to cite

APA:

Huang, R., Meier, W.J.H., Bräuning, A., Fu, P., Fan, Z., Aryal, S.,... Grießinger, J. (2026). Water use complementarity in old-growth mixed forests versus competition in younger successional mixed forests. Agricultural and Forest Meteorology, 386. https://doi.org/10.1016/j.agrformet.2026.111226

MLA:

Huang, Ru, et al. "Water use complementarity in old-growth mixed forests versus competition in younger successional mixed forests." Agricultural and Forest Meteorology 386 (2026).

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