The fluvial architecture of buried floodplain sediments of the Weiße Elster River (Germany) revealed by a novel method combination of drill cores with two‐dimensional and spatially resolved geophysical measurements

The complex and non-linear fluvial river dynamics are characterized by repeated periods of fluvial erosion and re-deposition in different parts of the floodplain. Understanding the fluvial architecture (i.e. the three-dimensional arrangement and genetic interconnectedness of different sediment types) is therefore fundamental to obtain well-based information about controlling factors. However, investigating the fluvial architecture in buried floodplain deposits without natural exposures is challenging. We studied the fluvial architecture of the middle Weiße Elster floodplain in Central Germany, an extraordinary long-standing archive of Holocene flooding and landscape changes in sensitive loess-covered Central European landscapes. We applied a novel systematic approach by coupling two-dimensional transects of electrical resistivity tomography (ERT) measurements and closely spaced core drillings with spatially resolved measurements of electromagnetic induction (EMI) of larger floodplain areas at three study sites. This allowed for (i) time and cost-efficient core drillings based on preceding ERT measurements and (ii) spatially scaling up the main elements of the fluvial architecture, such as the distribution of thick silt-clay overbank deposits and paleochannel patterns from the floodplain transects to larger surrounding areas. We found that fine-grained sand and silt-clay overbank deposits overlying basal gravels were deposited during several periods of intensive flooding. Those were separated from each other by periods of reduced flooding, allowing soil formation. However, the overbank deposits were severely laterally eroded before and during each sedimentation period. This was probably linked with pronounced meandering or even braiding of the river. Our preliminary chronological classification suggests that first fine-grained sedimentation must have occurred during the Early to Middle Holocene, and the last phase of lateral erosion and sedimentation during the Little Ice Age. Our study demonstrates the high archive potential of the buried fluvial sediments of the middle Weiße Elster floodplain and provides a promising time and cost-effective approach for future studies of buried floodplain sediments

Mach-, Reynolds- and Sweep Effects on Active Flow Separation Control Effectivity on a 2-Element Airfoil Wing

Over the last decade numerous experimental and numerical studies have been conducted by DLR together with partners regarding the maturation of active flow seperation control technologies at low speed high-lift conditions. The DLR-F15 high-lift airfoil has been established as a common test bed for such kind of investigations within the German national framework and in the scope of European Research. The present paper highlights major results of this research regarding flow seperation suppression by means of pulsed blowing

Distribution of Chernozems and Phaeozems in Central Germany during the Neolithic period

A well-based knowledge about the former distribution of Chernozems and Phaeozems is necessary to (i) better understand the factors influencing formation and degradation of these highly fertile soils, and (ii) better explain prehistoric settlement patterns that were also determined by natural factors such as soil fertility. During this archaeopedological study carried out in Central Germany we applied sedimentological and micromorphological methods to compare soils and pedosediments from the recent Chernozem/Phaeozem region with black-coloured pedosediments buried in early Neolithic structures of the recent Luvisol area directly to the east. Relocated clay coatings and significantly lower magnetic enhancement compared to Chernozem/Phaeozem-derived material were found in most black-coloured pedosediments in the Luvisol area. This demonstrates that despite their location next to an extensive Chernozem/Phaeozem area these sediments do not originate from Chernozems or Phaeozems. Instead, their dark colour must either originate from anthropogenic input similar to black-coloured Anthrosols (“Dark Earth”), or must stem from Ah-material of former Luvisols. Consequently, may be apart from a small relatively dry and carbonate-rich Luvisol region northwest of Leipzig there was obviously no significantly larger distribution of Neolithic Chernozems and Phaeozems in this region during the past. Consequently, the regional early Neolithic settlers of the Linear Pottery Culture settled intensively also in areas outside the distribution of Chernozems and Phaeozems, and the activities of these settlers did not lead to the formation of such soils. Thus, fertile soils were obviously only one factor among probably others to explain the regional Neolithic settlement pattern. Significantly lower carbonate contents were found for the parent material of the black-coloured pedosediments in the Luvisol region compared with the parent material of Chernzems and Phaeozems. This demonstrates that the decisive factor to explain the recent and former spatial distribution of Chernozems and Phaeozems in this relatively dry area is the carbonate dynamics. Anthropogenic activity since the early Neolithic period obviously helped to preserve the naturally formed Chernozems and Phaeozems by re-carbonatization processes, but humans were not the main soil forming factor in early settled regions