ePrints@IIScePrints@IISc Home | About | Browse | Latest Additions | Advanced Search | Contact | Help

The roots of the drought: Hydrology and water uptake strategies mediate forest-wide demographic response to precipitation

Chitra-Tarak, Rutuja and Ruiz, Laurent and Dattaraja, Handanakere S and Kumar, M S Mohan and Riotte, Jean and Suresh, Hebbalalu S and McMahon, Sean M and Sukumar, Raman (2018) The roots of the drought: Hydrology and water uptake strategies mediate forest-wide demographic response to precipitation. In: JOURNAL OF ECOLOGY, 106 (4). pp. 1495-1507.

[img] PDF
Jou_Eco_106-4_1495_2018.pdf - Published Version
Restricted to Registered users only

Download (1MB) | Request a copy
Official URL: https://dx.doi.org/10.1111/1365-2745.12925


1. Drought-induced tree mortality is expected to increase globally due to climate change, with profound implications for forest composition, function and global climate feedbacks. How drought is experienced by different species is thought to depend fundamentally on where they access water vertically below-ground, but this remains untracked so far due to the difficulty of measuring water availability at depths at which plants access water (few to several tens of metres), the broad temporal scales at which droughts at those depths unfold (seasonal to decadal), and the difficulty in linking these patterns to forest-wide species-specific demographic responses. 2. We address this problem through a new eco-hydrological framework: we used a hydrological model to estimate below-ground water availability by depth over a period of two decades that included a multi-year drought. Given this water availability scenario and 20year long-records of species-specific growth patterns, we inversely estimated the relative depths at which 12 common species in the forest accessed water via a model of water stress. Finally, we tested whether our estimates of species relative uptake depths predicted mortality in the multi-year drought. 3. The hydrological model revealed clear below-ground niches as precipitation was decoupled from water availability by depth at multi-annual scale. Species partitioned the hydrological niche by diverging in their uptake depths and so in the same forest stand, different species experienced very different drought patterns, resulting in clear differences in species-specific growth. Finally, species relative water uptake depths predicted species mortality patterns after the multi-year drought. Species that our method ranked as relying on deeper water were the ones that had suffered from greater mortality, as the zone from which they access water took longer to recharge after depletion. 4. Synthesis. This research changes our understanding of how hydrological niches operate for trees, with a trade-off between realized growth potential and survival under drought with decadal scale return time. The eco-hydrological framework highlights the importance of species-specific below-ground strategies in predicting forest response to drought. Applying this framework more broadly may help us better understand species coexistence in diverse forest communities and improve mechanistic predictions of forests productivity and compositional change under future climate.

Item Type: Journal Article
Publisher: WILEY, 111 RIVER ST, HOBOKEN 07030-5774, NJ USA
Additional Information: Copy right of this article belong to WILEY, 111 RIVER ST, HOBOKEN 07030-5774, NJ USA
Department/Centre: Division of Biological Sciences > Centre for Ecological Sciences
Division of Mechanical Sciences > Divecha Centre for Climate Change
Date Deposited: 02 Jul 2018 14:54
Last Modified: 12 Oct 2018 15:10
URI: http://eprints.iisc.ac.in/id/eprint/60111

Actions (login required)

View Item View Item