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“Planting water” is possible – against aridity and droughts
The water regime of landscapes is commuting more and more between the extremes drought and flooding. The type of vegetation and land use plays an important role in water retention and runoff. Together with scientists from the United Kingdom and the USA, researchers from the German Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) in Berlin have developed a mathematical model that can reflect the complex interplays between vegetation, soil and water regimes. They show, for example, that in beech forests water is increasingly cycled between soil and vegetation to increase evaporation to the atmosphere, while grass cover promotes groundwater recharge.
A mathematical model to quantify soil-water interplays
With the EcH2o-iso they have developed, the researchers can quantify where, how and for how long water is stored and released in the landscape. The model helps in better predicting the effects of land-use changes on the water balance under changing climatic conditions. In drought-prone areas in particular, this knowledge can support the creation of land use strategies that increase the landscape's resistance to climate change and protect water resources.
"So far, the type of vegetation has been considered primarily with a view to preventing soil erosion. In view of more frequent extreme weather events such as droughts and floods, however, it is increasingly a question of which plants can be cultivated to control the retention or loss of water in the landscape," says Dörthe Tetzlaff, head of the study, leader of the research group “Landscape Ecohydrology” at IGB and Professor in Ecohydrology at Humboldt University Berlin.
Previous forecasting models often capture vegetation as a static element. Thus, the complex interactions between evapotranspiration – the evaporation of water by plants and of soil and water surfaces – and the physiological processes of plants could only be insufficiently understood.
In this study, however, long-term data of direct vegetation measures, (e.g. biomass production and transpiration), was used as well. This improves the reliability of the models and their transferability. In the field, the models were tested with so-called conservative tracers. These are markers that can be applied to determine the age and origin of the water. This is a novel approach to assess the effects of climate change on the water balance.
In a region around Lake Stechlin in northern Germany, the researchers validated the model using field studies. They compared land areas with deciduous forest and grass cover. The results of the field study show that grassland use leads to more groundwater recharge and that in beech forests more water is returned to the atmosphere by evapotranspiration. However, the effects are site-specific and depend on the respective hydroclimate, biogeography and landscape ecology.
With the help of the EcH2o-iso model, however, these differences can be taken into account in the future, and local as well as large-scale forecast models can be created.
Doerte Tetzlaff et al.: Ecohydrological modelling with EcH2O‐iso to quantify forest and grassland effects on water partitioning and flux ages. In Hydrological processes, May 2019, doi.org/10.1002/hyp.13480