Theories attempting to explain species coexistence in plant communities have argued in favor of species’ capacities to occupy a multidimensional niche with spatial, temporal and biotic axes. We used the concept of hydrological niche segregation to learn how ecological niches are structured both spatially and temporally and whether small scale humidity gradients between adjacent niches are the main factor explaining water partitioning among tree species in a highly water-limited semiarid forest ecosystem. By combining geophysical methods, isotopic ecology, plant ecophysiology and anatomical measurements, we show how coexisting pine and oak species share, use and temporally switch between diverse spatially distinct niches by employing a set of functionally coupled plant traits in response to changing environmental signals. We identified four geospatial niches that turned into nine, when considering the temporal dynamics of the wetting/drying cycles in the substrate and the particular plant species adaptations to garner, transfer, store and use water. Under water scarcity, pine and oak exhibited water use segregation from different niches, yet under maximum drought when oak trees crossed physiological thresholds, niche overlap occurred. The identification of niches and mechanistic understanding of when and how species use them will help unify theories of plant coexistence and competition.

The Geodiversity involves substrate characteristics such as degree of fractured rock, fracture depth, soil depth, parental rock, soil texture, etc., that affect the hidrology of substrates and subsequently the availability of water for plants. Here we examined the importance of the geological substrate, as a factor that triggers the incidence of forest decline. We demonstrated that characteristics of the geological substrate related to the limitation of water availability enhances Tillandsia recurvata (Tire) infestation and eventually causes loss of vigor in oak trees. Using electrical resistivity tomography (geophysical methods) and stable isotope techniques (δ18O / δ16O), we showed that substrates dominated by regolith and rocks imposed greater conditions of drought to an oak forest stand than a substrate with a more granulated material. Trees in this forest stand presented greater densities of Tire, a plant considered as epiphyte. However, under the observed conditions of high infestation, Tire apparently exhibited a change from epiphytic to parasitic plant as it acquired water from oak. This study identified that the structural composition of the substrate (i.e. geodiversity) is a factor accelerating the processes of decay and likely forest mortality related to the effects of drought and the infestation by pests and diseases.