TY - THES A1 - Dräger, Nadine T1 - Holocene climate and environmental variability in NE Germany inferred from annually laminated lake sediments T1 - Rekonstruktion Holozäner Klima- und Umweltveränderungen in NO Deutschland anhand von jährlich geschichteten Seesedimenten N2 - Understanding the role of natural climate variability under the pressure of human induced changes of climate and landscapes, is crucial to improve future projections and adaption strategies. This doctoral thesis aims to reconstruct Holocene climate and environmental changes in NE Germany based on annually laminated lake sediments. The work contributes to the ICLEA project (Integrated CLimate and Landscape Evolution Analyses). ICLEA intends to compare multiple high-resolution proxy records with independent chronologies from the N central European lowlands, in order to disentangle the impact of climate change and human land use on landscape development during the Lateglacial and Holocene. In this respect, two study sites in NE Germany are investigated in this doctoral project, Lake Tiefer See and palaeolake Wukenfurche. While both sediment records are studied with a combination of high-resolution sediment microfacies and geochemical analyses (e.g. µ-XRF, carbon geochemistry and stable isotopes), detailed proxy understanding mainly focused on the continuous 7.7 m long sediment core from Lake Tiefer See covering the last ~6000 years. Three main objectives are pursued at Lake Tiefer See: (1) to perform a reliable and independent chronology, (2) to establish microfacies and geochemical proxies as indicators for climate and environmental changes, and (3) to trace the effects of climate variability and human activity on sediment deposition. Addressing the first aim, a reliable chronology of Lake Tiefer See is compiled by using a multiple-dating concept. Varve counting and tephra findings form the chronological framework for the last ~6000 years. The good agreement with independent radiocarbon dates of terrestrial plant remains verifies the robustness of the age model. The resulting reliable and independent chronology of Lake Tiefer See and, additionally, the identification of nine tephras provide a valuable base for detailed comparison and synchronization of the Lake Tiefer See data set with other climate records. The sediment profile of Lake Tiefer See exhibits striking alternations between well-varved and non-varved sediment intervals. The combination of microfacies, geochemical and microfossil (i.e. Cladocera and diatom) analyses indicates that these changes of varve preservation are caused by variations of lake circulation in Lake Tiefer See. An exception is the well-varved sediment deposited since AD 1924, which is mainly influenced by human-induced lake eutrophication. Well-varved intervals before the 20th century are considered to reflect phases of reduced lake circulation and, consequently, stronger anoxic conditions. Instead, non-varved intervals indicate increased lake circulation in Lake Tiefer See, leading to more oxygenated conditions at the lake ground. Furthermore, lake circulation is not only influencing sediment deposition, but also geochemical processes in the lake. As, for example, the proxy meaning of δ13COM varies in time in response to changes of the oxygen regime in the lake hypolinion. During reduced lake circulation and stronger anoxic conditions δ13COM is influenced by microbial carbon cycling. In contrast, organic matter degradation controls δ13COM during phases of intensified lake circulation and more oxygenated conditions. The varve preservation indicates an increasing trend of lake circulation at Lake Tiefer See after ~4000 cal a BP. This trend is superimposed by decadal to centennial scale variability of lake circulation intensity. Comparison to other records in Central Europe suggests that the long-term trend is probably related to gradual changes in Northern Hemisphere orbital forcing, which induced colder and windier conditions in Central Europe and, therefore, reinforced lake circulation. Decadal to centennial scale periods of increased lake circulation coincide with settlement phases at Lake Tiefer See, as inferred from pollen data of the same sediment record. Deforestation reduced the wind shelter of the lake, which probably increased the sensitivity of lake circulation to wind stress. However, results of this thesis also suggest that several of these phases of increased lake circulation are additionally reinforced by climate changes. A first indication is provided by the comparison to the Baltic Sea record, which shows striking correspondence between major non-varved intervals at Lake Tiefer See and bioturbated sediments in the Baltic Sea. Furthermore, a preliminary comparison to the ICLEA study site Lake Czechowskie (N central Poland) shows a coincidence of at least three phases of increased lake circulation in both lakes, which concur with periods of known climate changes (2.8 ka event, ’Migration Period’ and ’Little Ice Age’). These results suggest an additional over-regional climate forcing also on short term increased of lake circulation in Lake Tiefer See. In summary, the results of this thesis suggest that lake circulation at Lake Tiefer See is driven by a combination of long-term and short-term climate changes as well as of anthropogenic deforestation phases. Furthermore, the lake circulation drives geochemical cycles in the lake affecting the meaning of proxy data. Therefore, the work presented here expands the knowledge of climate and environmental variability in NE Germany. Furthermore, the integration of the Lake Tiefer See multi-proxy record in a regional comparison with another ICLEA side, Lake Czechowskie, enabled to better decipher climate changes and human impact on the lake system. These first results suggest a huge potential for further detailed regional comparisons to better understand palaeoclimate dynamics in N central Europe. N2 - Es ist von großer Bedeutung die natürliche Klimavariabilität unter dem Einfluss menschlich verursachter Klimaänderungen zu verstehen, um Zukunftsprognosen und Adaptionsstrategien zu verbessern. Die Hauptzielsetzung der vorliegenden Doktorarbeit ist die Rekonstruktion von Klima- und Umweltveränderungen während des Holozäns in NO Deutschland anhand von jährlich geschichteten Seesedimenten. Diese Arbeit ist ein Beitrag zum ICLEA Projekt (integrierte Klima- und Landschaftsentwicklungsanalyse). ICLEA strebt den Vergleich von mehreren hochaufgelösten Proxy- Archiven aus dem Nord-zentral europäischen Tiefland an, um Einflüsse von Mensch und Klima auf die Landschaftsentwicklung auseinander zu dividieren. Demnach werden in diesem Doktorprojekt zwei Gebiete untersucht: der Tiefe See und der verlandete See Wukenfurche. Während beide Sedimentarchive mit einer Kombination aus hochaufgelösten sedimentmikrofaziellen und -geochemischen Methoden untersucht werden, konzentriert sich die detaillierte Untersuchung der Proxy-Bedeutung auf den kontinuierlichen 7,7mlangen Sedimentkern vom Tiefer See, der die letzten 6000 Jahre abdeckt. Drei Hauptziele werden am Tiefen See verfolgt: (1) das Erstellen einer robusten und unabhängigen Chronologie (2) das Etablieren von mikrofaziellen und geochemischen Proxies als Indikatoren für Klima- und Landschaftsveränderungen und (3) das Ableiten von Klimaveränderungen und menschlichem Einfluss auf die Sedimentablagerung. Zum Erreichen des ersten Zieles wurde eine robuste Chronologie mit Hilfe eines multiplen Datierungsansatzes erstellt. Das Zusammenführen der Warvenzählung und Tephra-Funden bildet dabei das Gerüst für die Chronologie der letzten 6000 Jahre, deren Stabilität durch die gute Übereinstimmung mit unabhängigen Radiokarbondatierungen bestätigt wird. Diese robuste und unabhängige Chronologie und die zusätzlichen neun Tephra-Funde bieten die Basis für den detaillierten Vergleich und die Synchronisation des Tiefen See Datensatzes mit anderen Klimaarchiven. Das Sedimentprofil vom Tiefen See zeigt markante Wechsel zwischen gut warvierten und nicht warvierten Sedimentabschnitten auf. Die kombinierte Untersuchung der Mikrofazies, der Geochemie und von Mikrofossilien (d.h. Cladoceren und Diatomeen) zeigte, dass diese Veränderungen der Warvenerhaltung auf Änderungen der Seezirkulation zurückzuführen sind. Ausgenommen ist der rezente warvierte Abschnitt ab AD 1924, der hauptsächlich durch menschlich verursachte Seeeutrophierung beeinflusst ist. Warvierte Abschnitte vor dem 20. Jahrhundert sind durch verringerte Seezirkulation und die damit verbundenen stärkeren anoxischen Bedingungen im See hervorgerufen worden. Die Ablagerung von nicht warvierten Sedimenten weist auf stärkere Seezirkulation und sauerstoffreichere Bedingungen am Seegrund hin. Die Seezirkulation beeinflusst zusätzlich zum Sedimentmuster auch geochemische Prozesse im See. Zum Beispiel verändert sich die Proxy-Bedeutung der stabilen Kohlenstoffisotope von organischem Material (δ13COM) in Reaktion auf das veränderte Sauerstoffregime. Während geringer Seezirkulation und stärkeren anoxischen Bedingungen werden stark negative δ13COM Werte durch mikrobielle Aktivität hervorgerufen. Im Gegensatz verursachen Phasen mit verstärkter Seezirkulation positivere δ13COM Werte, was vermutlich auf stärkeren Abbau von organischem Material im sauerstoffangereicherten Milieu am Seegrund zurückzuführen ist. Die Warvenerhaltung zeigt einen ansteigenden Trend der Seezirkulation im Tiefen See nach ungefähr 4000 Jahre vor heute an. Dieser Trend ist überlagert mit kurzzeitigen Seezirkulationsveränderungen auf dekadischen Zeitskalen. Der Vergleich mit anderen Archiven in Zentral-Europa lässt darauf schließen, dass der Langzeittrend wahrscheinlich auf graduelle Veränderungen der orbitalen Parameter zurückzuführen ist, was kühlere und windigere Bedingungen in Zentral-Europa hervorgerufen hatte und damit die Seezirkulation im Tiefen See verstärkt hat. Die kurzzeitigen Phasen von verstärkter Seezirkulation fallen mit Siedlungsperioden am Tiefen See zusammen, die mit Pollendaten vom selben Sedimentkern rekonstruiert wurden. Die Waldrodung verringerte den Windschutz des Sees, was möglicherweise zu einer erhöhten Sensitivität der Seezirkulation zu Windstress geführt hat. Ein erster Vergleich des Tiefen Sees zu dem ICLEA Untersuchungsgebiet des Czechowskie See zeigt, dass in beiden Seen drei gemeinsame Phasen verstärkter Seezirkulation auftreten, die auch mit bekannten Zeiten veränderter Klimabedingungen zusammenfallen (2.8 ka event, Migrationsperiode und die Kleine Eiszeit). Diese Ergebnisse zeigen, dass die Seezirkulation von einer Kombination aus Klimaveränderung auf langen und kurzen Zeitskalen und der Abholzung des Menschen angetrieben wird. Zusammengefasst erweitert die hier vorliegende Arbeit das Wissen von Klima und Umweltveränderungen in NO Deutschland. Zudem wird gezeigt, dass ein regionaler Vergleich verschiedener Untersuchungsgebieten mit unabhängigen Chronologien ein verbessertes Auseinanderhalten von Klimaeinflüssen und menschlichen Einflüssen auf die Seesysteme ermöglicht. Damit kann ein verbessertes Verständnis der Paläoklimadynamik in Zentral-Europa gewonnen werden. KW - palaeoclimate KW - Paläoklima KW - Holocene KW - Holozän KW - varved lake sediments KW - warvierte Seesedimente KW - Tiefer See KW - Tiefer See KW - human impact KW - menschliche Einflüsse Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-103037 ER - TY - JOUR A1 - Dräger, Nadine A1 - Plessen, Birgit A1 - Kienel, Ulrike A1 - Siowinski, Michat A1 - Ramisch, Arne A1 - Tjallingii, Rik A1 - Pinkerneil, Sylvia A1 - Brauer, Achim T1 - Hypolimnetic oxygen conditions influence varve preservation and delta C-13 of sediment organic matter in Lake Tiefer See, NE Germany JF - Journal of paleolimnolog N2 - Stable carbon isotopes of sediment organic matter (delta C-13(OM)) are widely applied in paleoenvironmental studies. Interpretations of delta C-13(OM), however, remain challenging and factors that influence delta C-13(OM) may not apply across all lakes. Common explanations for stratigraphic shifts in delta C-13(OM) include changes in lake productivity or changes in inputs of allochthonous OM. We investigated the influence of different oxygen conditions (oxic versus anoxic) on the delta C-13(OM) values in the sediments of Lake Tiefer See. We analysed (1) a long sediment core from the deepest part of the lake, (2) two short, sediment-water interface cores from shallower water depths, and (3) OM in the water column, i.e. from sediment traps. Fresh OM throughout the entire water column showed a relatively constant delta C-13(OM) value of approximately -30.5 parts per thousand. Similar values, about -31 parts per thousand, were obtained for well-varved sediments in both the long and short, sediment-water interface cores. In contrast, delta C-13(OM) values from non-varved sediments in all cores were significantly less negative (-29 parts per thousand). The delta C-13(OM) values in the sediment-water interface cores from different water depths differ for sediments of the same age, if oxygen conditions at the time of deposition were different at these sites, as suggested by the state of varve preservation. Sediments deposited from AD 1924 to 1980 at 62m water depth are varved and exhibit delta C-13(OM) values around -31 parts per thousand, whereas sediments of the same age in the core from 35m water depth are not varved and show less negative delta C-13(OM) values of about -29 parts per thousand. The relation between varve occurrence and delta C-13(OM) values suggests that delta C-13(OM) is associated with oxygen conditions because varve preservation depends on hypolimnetic anoxia. A mechanism that likely influences delta C-13(OM) is selective degradation of OM under oxic conditions, such that organic components with more negative delta C-13(OM) are preferably decomposed, leading to less negative delta C-13(OM) values in the remaining, undegraded OM pool. Greater decomposition of OM in non-varved sediments is supported by lower TOC concentrations in these deposits (similar to 5%) compared to well-varved sediments (similar to 15%). Even in lakes that display small variations in productivity and terrestrial OM input through time, large spatial and temporal differences in hypolimnetic oxygen concentrations may be an important factor controlling sediment delta C-13(OM). KW - Carbon stable isotopes KW - Hypolimnetic oxygen KW - Organic matter degradation KW - Varves Y1 - 2019 U6 - https://doi.org/10.1007/s10933-019-00084-2 SN - 0921-2728 SN - 1573-0417 VL - 62 IS - 2 SP - 181 EP - 194 PB - Springer CY - Dordrecht ER - TY - JOUR A1 - Heinrich, Ingo A1 - Balanzategui, Daniel A1 - Bens, Oliver A1 - Blasch, Gerald A1 - Blume, Theresa A1 - Boettcher, Falk A1 - Borg, Erik A1 - Brademann, Brian A1 - Brauer, Achim A1 - Conrad, Christopher A1 - Dietze, Elisabeth A1 - Dräger, Nadine A1 - Fiener, Peter A1 - Gerke, Horst H. A1 - Güntner, Andreas A1 - Heine, Iris A1 - Helle, Gerhard A1 - Herbrich, Marcus A1 - Harfenmeister, Katharina A1 - Heussner, Karl-Uwe A1 - Hohmann, Christian A1 - Itzerott, Sibylle A1 - Jurasinski, Gerald A1 - Kaiser, Knut A1 - Kappler, Christoph A1 - Koebsch, Franziska A1 - Liebner, Susanne A1 - Lischeid, Gunnar A1 - Merz, Bruno A1 - Missling, Klaus Dieter A1 - Morgner, Markus A1 - Pinkerneil, Sylvia A1 - Plessen, Birgit A1 - Raab, Thomas A1 - Ruhtz, Thomas A1 - Sachs, Torsten A1 - Sommer, Michael A1 - Spengler, Daniel A1 - Stender, Vivien A1 - Stüve, Peter A1 - Wilken, Florian T1 - Interdisciplinary Geo-ecological Research across Time Scales in the Northeast German Lowland Observatory (TERENO-NE) JF - Vadose zone journal N2 - The Northeast German Lowland Observatory (TERENO-NE) was established to investigate the regional impact of climate and land use change. TERENO-NE focuses on the Northeast German lowlands, for which a high vulnerability has been determined due to increasing temperatures and decreasing amounts of precipitation projected for the coming decades. To facilitate in-depth evaluations of the effects of climate and land use changes and to separate the effects of natural and anthropogenic drivers in the region, six sites were chosen for comprehensive monitoring. In addition, at selected sites, geoarchives were used to substantially extend the instrumental records back in time. It is this combination of diverse disciplines working across different time scales that makes the observatory TERENO-NE a unique observation platform. We provide information about the general characteristics of the observatory and its six monitoring sites and present examples of interdisciplinary research activities at some of these sites. We also illustrate how monitoring improves process understanding, how remote sensing techniques are fine-tuned by the most comprehensive ground-truthing site DEMMIN, how soil erosion dynamics have evolved, how greenhouse gas monitoring of rewetted peatlands can reveal unexpected mechanisms, and how proxy data provides a long-term perspective of current ongoing changes. Y1 - 2018 U6 - https://doi.org/10.2136/vzj2018.06.0116 SN - 1539-1663 VL - 17 IS - 1 PB - Soil Science Society of America CY - Madison ER -