Infiltration and soil water dynamics in a tropical dry forest: it may be dry but definitely not arid

Authors

  • Kegan K. Farrick,

    Corresponding author
    1. Department of Earth Sciences, Western University, London, Ontario, Canada
    • Correspondence to: Kegan Farrick, Department of Earth Sciences, Western University, London, Ontario, Canada

      E-mail: kfarrick@uwo.ca

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  • Brian A. Branfireun

    1. Department of Biology and Centre for Environment and Sustainability, Western University, London, Ontario, Canada
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Abstract

Studies of hydrological processes in tropical dry forests are less than 1% of published forest hydrology literature. The strong dry-wet seasonality typical of the tropical dry forest ecoregion is similar to those that characterize semi-arid regions. In semi-arid systems, infiltration is often limited by low hydraulic conductivities (K) and extreme levels of soil water repellency, which when combined with high rainfall intensities, result in infiltration excess (Hortonian) overland flow (HOF) as a dominant runoff mechanism. Given that little is known about the surface runoff hydrology of tropical dry forests, we tested the hypothesis that our knowledge about controls on runoff in semi-arid systems is transferrable to tropical dry forest hillslopes. Our results show that tropical dry forest soils do develop a strong water repellency during the dry season; however, this does not persist through the wet season. In our period of study, surface K ranged from 9 to 164 mm/h and was greater than the rainfall intensity for more than 75% of the rain events. In our period of study, rainfall intensities were generally low with more than half of the storm events falling between 0.2 and 4.2 mm/h. The low rainfall intensities, high K and lack of repellent surfaces during the wet season result in the percolation of >70% of the annual rainfall through the upper 30 cm of soil, indicating that subsurface flow, not HOF, is the primary runoff mechanism. These findings show that in spite of similar climate and vegetation regimes, hydrological knowledge from semi-arid catchments is not transferrable to tropical dry forests. Copyright © 2014 John Wiley & Sons, Ltd.

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