TY - JOUR A1 - Calitri, Francesca A1 - Sommer, Michael A1 - Norton, Kevin A1 - Temme, Arnaud A1 - Brandova, Dagmar A1 - Portes, Raquel A1 - Christl, Marcus A1 - Ketterer, Mike E. A1 - Egli, Markus T1 - Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using Pu239+240 and Be-10 JF - Earth surface processes and landforms : the journal of the British Geomorphological Research Group N2 - Two principal groups of processes shape mass fluxes from and into a soil: vertical profile development and lateral soil redistribution. Periods having predominantly progressive soil forming processes (soil profile development) alternate with periods having predominantly regressive processes (erosion). As a result, short‐term soil redistribution – years to decades – can differ substantially from long‐term soil redistribution; i.e. centuries to millennia. However, the quantification of these processes is difficult and consequently their rates are poorly understood. To assess the competing roles of erosion and deposition we determined short‐ and long‐term soil redistribution rates in a formerly glaciated area of the Uckermark, northeast Germany. We compared short‐term erosion or accumulation rates using plutonium‐239 and ‐240 (239+240Pu) and long‐term rates using both in situ and meteoric cosmogenic beryllium‐10 (10Be). Three characteristic process domains have been analysed in detail: a flat landscape position having no erosion/deposition, an erosion‐dominated mid‐slope, and a deposition‐dominated lower‐slope site. We show that the short‐term mass erosion and accumulation rates are about one order of magnitude higher than long‐term redistribution rates. Both, in situ and meteoric 10Be provide comparable results. Depth functions, and therefore not only an average value of the topsoil, give the most meaningful rates. The long‐term soil redistribution rates were in the range of −2.1 t ha‐1 yr‐1 (erosion) and +0.26 t ha‐1 yr‐1 (accumulation) whereas the short‐term erosion rates indicated strong erosion of up to 25 t ha‐1 yr‐1 and accumulation of 7.6 t ha‐1 yr‐1. Our multi‐isotope method identifies periods of erosion and deposition, confirming the ‘time‐split approach’ of distinct different phases (progressive/regressive) in soil evolution. With such an approach, temporally‐changing processes can be disentangled, which allows the identification of both the dimensions of and the increase in soil erosion due to human influence KW - soil erosion KW - Be-10 KW - Pu239+240 KW - temporal evolution KW - moraine landscape KW - agricultural soils Y1 - 2019 U6 - https://doi.org/10.1002/esp.4612 SN - 0197-9337 SN - 1096-9837 VL - 44 IS - 9 SP - 1783 EP - 1798 PB - Wiley CY - Hoboken ER - TY - JOUR A1 - Herbrich, Marcus A1 - Gerke, Horst H. A1 - Sommer, Michael T1 - Root development of winter wheat in erosion-affected soils depending on the position in a hummocky ground moraine soil landscape JF - Journal of plant nutrition and soil science = Zeitschrift für Pflanzenernährung und Bodenkunde N2 - Agricultural soil landscapes of hummocky ground moraines are characterized by 3D spatial patterns of soil types that result from profile modifications due to the combined effect of water and tillage erosion. We hypothesize that crops reflect such soil landscape patterns by increased or reduced plant and root growth. Root development may depend on the thickness and vertical sequence of soil horizons as well as on the structural development state of these horizons at different landscape positions. The hypotheses were tested using field data of the root density (RD) and the root lengths (RL) of winter wheat using the minirhizotron technique. We compared data from plots at the CarboZALF-D site (NE Germany) that are representing a non-eroded reference soil profile (Albic Luvisol) at a plateau position, a strongly eroded profile at steep slope (Calcaric Regosol), and a depositional profile at the footslope (Anocolluvic Regosol). At each of these plots, three Plexiglas access tubes were installed down to approx. 1.5 m soil depth. Root measurements were carried out during the growing season of winter wheat (September 2014-August 2015) on six dates. The root length density (RLD) and the root biomass density were derived from RD values assuming a mean specific root length of 100 m g(-1). Values of RD and RLD were highest for the Anocolluvic Regosol and lowest for the Calcaric Regosol. The maximum root penetration depth was lower in the Anocolluvic Regosol because of a relatively high and fluctuating water table at this landscape position. Results revealed positive relations between below-ground (root) and above-ground crop parameters (i.e., leaf area index, plant height, biomass, and yield) for the three soil types. Observed root densities and root lengths in soils at the three landscape positions corroborated the hypothesis that the root system was reflecting erosion-induced soil profile modifications. Soil landscape position dependent root growth should be considered when attempting to quantify landscape scale water and element balances as well as agricultural productivity. KW - minirhizotron KW - root density KW - root lengths density KW - root biomass KW - root penetration KW - soil erosion KW - soil horizonation Y1 - 2018 U6 - https://doi.org/10.1002/jpln.201600536 SN - 1436-8730 SN - 1522-2624 VL - 181 IS - 2 SP - 147 EP - 157 PB - Wiley-VCH CY - Weinheim ER - TY - JOUR A1 - Schmidt, Lena Katharina A1 - Zimmermann, Alexander A1 - Elsenbeer, Helmut T1 - Ant mounds as a source of sediment in a tropical rainforest? JF - Hydrological processes N2 - In Lutzito catchment on Barro Colorado Island, Panama, extraordinarily high suspended-sediment yields of 1-2Mgha-1year-1 were generated despite the dense forest cover coinciding with erosion-resistant soils. We hypothesized that ant mounding activity is an important zoogeomorphological mechanism in this area, providing relevant quantities of easily transportable material at the soil surface. To test this hypothesis, all ant mound material was collected collected for dry mass determination from thirty 4m2 plots installed in the study area every 1-3days during the 39-day sampling period. Additionally, three ground-nesting ant species responsible for mounds in the study area, Ectatomma ruidum, Trachymyrmex cornetzi and Strumigenys marginiventris, were identified. On the basis of the total of 1.38kg of material collected in the wet season of 2011, the estimate for the whole 8months wet season amounts to 725kgha-1. As this value is in the same order of magnitude as sediment output, it shows that ants may act as important ecosystem engineers and contribute to sediment production here by providing large quantities of fine-grained, readily erodible material at the soil surface for subsequent transport to the streambed. Copyright (c) 2014 John Wiley & Sons, Ltd. KW - ant mounds KW - soil erosion KW - sediment output KW - zoogeomorphology Y1 - 2014 U6 - https://doi.org/10.1002/hyp.10222 SN - 0885-6087 SN - 1099-1085 VL - 28 IS - 13 SP - 4156 EP - 4160 PB - Wiley-Blackwell CY - Hoboken ER - TY - JOUR A1 - Hoffmann, Thomas A1 - Schlummer, Manuela A1 - Notebaert, Bastiaan A1 - Verstraeten, Gert A1 - Korup, Oliver T1 - Carbon burial in soil sediments from Holocene agricultural erosion, Central Europe JF - Global biogeochemical cycles N2 - Natural and human-induced erosion supplies high amounts of soil organic carbon (OC) to terrestrial drainage networks. Yet OC fluxes in rivers were considered in global budgets only recently. Modern estimates of annual carbon burial in inland river sediments of 0.6 Gt C, or 22% of C transferred from terrestrial ecosystems to river channels, consider only lakes and reservoirs and disregard any long-term carbon burial in hillslope or floodplain sediments. Here we present the first assessment of sediment-bound OC storage in Central Europe from a synthesis of similar to 1500 Holocene hillslope and floodplain sedimentary archives. We show that sediment storage increases with drainage-basin size due to more extensive floodplains in larger river basins. However, hillslopes retain hitherto unrecognized high amounts of eroded soils at the scale of large river basins such that average agricultural erosion rates during the Holocene would have been at least twice as high as reported previously. This anthropogenic hillslope sediment storage exceeds floodplain storage in drainage basins <10(5) km(2), challenging the notion that floodplains are the dominant sedimentary sinks. In terms of carbon burial, OC concentrations in floodplains exceed those on hillslopes, and net OC accumulation rates in floodplains (0.70.2 g C m(-2)a(-1)) surpass those on hillslopes (0.40.1 g C m(-2)a(-1)) over the last 7500 years. We conclude that carbon burial in floodplains and on hillslopes in Central Europe exceeds terrestrial carbon storage in lakes and reservoirs by at least 2 orders of magnitude and should thus be considered in continental carbon budgets. KW - soil organic carbon KW - human impact KW - soil erosion KW - hillslope KW - floodplain KW - deposition Y1 - 2013 U6 - https://doi.org/10.1002/gbc.20071 SN - 0886-6236 SN - 1944-9224 VL - 27 IS - 3 SP - 828 EP - 835 PB - American Geophysical Union CY - Washington ER -