TY  - JOUR
A1  - Marquart, Arnim
A1  - Eldridge, David J.
A1  - Geissler, Katja
A1  - Lobas, Christoph
A1  - Blaum, Niels
T1  - Interconnected effects of shrubs, invertebrate-derived macropores and soil texture on water infiltration in a semi-arid savanna rangeland
JF  - Land degradation & development
N2  - Many semi arid savannas are prone to degradation, caused for example, by overgrazing or extreme climatic events, which often lead to shrub encroachment. Overgrazing by livestock affects vegetation and infiltration processes by directly altering plant composition (selective grazing) or by impacting soil physical properties (trampling). Water infiltration is controlled by several parameters, such as macropores (created by soil-burrowing animals or plant roots) and soil texture, but their effects have mostly been studied in isolation. Here we report on a study, in which we conducted infiltration experiments to analyze the interconnected effects of invertebrate-created macropores, shrubs and soil texture (sandy soil and loamy sand) on infiltration in two Namibian rangelands. Using structural equation modeling, we found a direct positive effect of shrub size on infiltration and indirectly via invertebrate macropores on both soil types. On loamy sands this effect was even stronger, but additionally, invertebrate-created macropores became relevant as a direct driver of infiltration. Our results provide new insights into the effects of vegetation and invertebrates on infiltration under different soil textures. Pastoralists should use management strategies that maintain a heterogeneous plant community that supports soil fauna to sustain healthy soil water dynamics, particularly on soils with higher loam content. Understanding the fundamental functioning of soil water dynamics in drylands is critical because these ecosystems are water-limited and support the livelihoods of many cultures worldwide.
KW  - hydrology
KW  - infiltration
KW  - invertebrate macropores
KW  - shrub-encroachment
KW  - soil function
KW  - soil texture
Y1  - 2020
U6  - https://doi.org/10.1002/ldr.3598
SN  - 1085-3278
SN  - 1099-145X
VL  - 31
IS  - 16
SP  - 2307
EP  - 2318
PB  - Wiley
CY  - Chichester, Sussex
ER  - 
TY  - JOUR
A1  - Marquart, Arnim
A1  - Goldbach, Lars
A1  - Blaum, Niels
T1  - Soil-texture affects the influence of termite macropores on soil water infiltration in a semi-arid savanna
JF  - Ecohydrology : ecosystems, land and water process interactions, ecohydrogeomorphology
N2  - Subterranean termites create tunnels (macropores) for foraging that can influence water infiltration and may lead to preferential flow to deeper soil layers. This is particularly important in water limited ecosystems such as semi-arid, agriculturally utilized savannas, which are particularly prone to land degradation and shrub-encroachment. Using termite activity has been suggested as a restoration measure, but their impact on hydrology is neither universal nor yet fully understood. Here, we used highly replicated, small-scale (50 x 50 cm) rain-simulation experiments to analyse the interacting effects of either vegetation (grass dominated vs. shrub dominated sites) or soil texture (sand vs. loamy sand) and termite foraging macropores on infiltration patterns. We used Brilliant Blue FCF as colour tracer to make the flow pathways in paired experiments visible, on either termite-disturbed soil or controls without surface macropores in two semi-arid Namibian savannas (with either heterogeneous soil texture or shrub cover). On highly shrub-encroached plots in the savanna site with heterogeneous soil texture, termite macropores increased maximum infiltration depth and total amount of infiltrated water on loamy sand, but not on sandy soil. In the sandy savanna with heterogeneous shrub cover, neither termite activity nor shrub density affected the infiltration. Termite's effect on infiltration depends on the soil's hydraulic conductivity and occurs mostly under ponded conditions, intercepting run-off. In semi-arid savanna soils with a considerable fraction of fine particles, termites are likely an important factor for soil water dynamics.
KW  - ecosystem functioning
KW  - infiltration
KW  - macropores
KW  - rain-simulation
KW  - shrub-encroachment
KW  - soil texture
KW  - termites
Y1  - 2020
U6  - https://doi.org/10.1002/eco.2249
SN  - 1936-0584
SN  - 1936-0592
VL  - 13
IS  - 8
PB  - Wiley
CY  - Chichester
ER  - 
TY  - JOUR
A1  - Mohr, Christian Heinrich
A1  - Coppus, Ruben
A1  - Iroume, Andres
A1  - Huber, Anton
A1  - Bronstert, Axel
T1  - Runoff generation and soil erosion processes after clear cutting
JF  - Journal of geophysical research : Earth surface
N2  - Timber harvesting by clear cutting is known to impose environmental impacts, including severe disturbance of the soil hydraulic properties which intensify the frequency and magnitude of surface runoff and soil erosion. However, it remains unanswered if harvest areas act as sources or sinks for runoff and soil erosion and whether such behavior operates in a steady state or evolves through time. For this purpose, 92 small-scale rainfall simulations of different intensities were carried out under pine plantation conditions and on two clear-cut harvest areas of different age. Nonparametrical Random Forest statistical models were set up to quantify the impact of environmental variables on the hydrological and erosion response. Regardless of the applied rainfall intensity, runoff always initiated first and yielded most under plantation cover. Counter to expectations, infiltration rates increased after logging activities. Once a threshold rainfall intensity of 20mm/h was exceeded, the younger harvest area started to act as a source for both runoff and erosion after connectivity was established, whereas it remained a sink under lower applied rainfall intensities. The results suggest that the impact of microtopography on surface runoff connectivity and water-repellent properties of the topsoil act as first-order controls for the hydrological and erosion processes in such environments. Fast rainfall-runoff response, sediment-discharge-hystereses, and enhanced postlogging groundwater recharge at catchment scale support our interpretation. At the end, we show the need to account for nonstationary hydrological and erosional behavior of harvest areas, a fact previously unappreciated in predictive models.
KW  - infiltration
KW  - runoff
KW  - erosion
KW  - connectivity
KW  - rainfall simulation
KW  - catchment
Y1  - 2013
U6  - https://doi.org/10.1002/jgrf.20047
SN  - 2169-9003
VL  - 118
IS  - 2
SP  - 814
EP  - 831
PB  - American Geophysical Union
CY  - Washington
ER  -