TY - THES A1 - Pusch, Martin T1 - Horizontale und vertikale Konnektivität in Fließgewässern und Seen : ökologische Funktionen und anthropogene Überformung T1 - Horizontal and vertical connectivity in rivers and lakes : ecological functions and anthropogenic transformation N2 - Gewässer werden traditionellerweise als abgeschlossene Ökosysteme gesehen, und insbeson¬dere das Zirkulieren von Wasser und Nährstoffen im Pelagial von Seen wird als Beispiel dafür angeführt. Allerdings wurden in der jüngeren Vergangenheit wichtige Verknüpfungen des Freiwasserkörpers von Gewässern aufgezeigt, die einerseits mit dem Benthal und andererseits mit dem Litoral, der terrestrischen Uferzone und ihrem Einzugsgebiet bestehen. Dadurch hat in den vergangen Jahren die horizontale und vertikale Konnektivität der Gewässerökosysteme erhöhtes wissenschaftliches Interesse auf sich gezogen, und damit auch die ökologischen Funktionen des Gewässergrunds (Benthal) und der Uferzonen (Litoral). Aus der neu beschriebenen Konnektivität innerhalb und zwischen diesen Lebensräumen ergeben sich weitreichende Konsequenzen für unser Bild von der Funktionalität der Gewässer. In der vorliegenden Habilitationsschrift wird am Beispiel von Fließgewässern und Seen des nordostdeutschen Flachlandes eine Reihe von internen und externen funktionalen Verknüpfungen in den horizontalen und vertikalen räumlichen Dimensionen aufgezeigt. Die zugrunde liegenden Untersuchungen umfassten zumeist sowohl abiotische als auch biologische Variablen, und umfassten thematisch, methodisch und hinsichtlich der Untersuchungsgewässer ein breites Spektrum. Dabei wurden in Labor- und Feldexperimenten sowie durch quantitative Feldmes¬sungen ökologischer Schlüsselprozesse wie Nährstoffretention, Kohlenstoffumsatz, extrazellu¬läre Enzymaktivität und Ressourcenweitergabe in Nahrungsnetzen (mittels Stabilisotopen¬methode) untersucht. In Bezug auf Fließgewässer wurden dadurch wesentliche Erkenntnisse hinsichtlich der Wirkung einer durch Konnekticität geprägten Hydromorphologie auf die die aquatische Biodiversität und die benthisch-pelagische Kopplung erbracht, die wiederum einen Schlüsselprozess darstellt für die Retention von in der fließenden Welle transportierten Stoffen, und damit letztlich für die Produktivität eines Flussabschnitts. Das Litoral von Seen wurde in Mitteleuropa jahrzehntelang kaum untersucht, so dass die durchgeführten Untersuchungen zur Gemeinschaftsstruktur, Habitatpräferenzen und Nahrungs¬netzverknüpfungen des eulitoralen Makrozoobenthos grundlegend neue Erkenntnisse erbrach¬ten, die auch unmittelbar in Ansätze zur ökologischen Bewertung von Seeufern gemäß EG-Wasserrahmenrichtlinie eingehen. Es konnte somit gezeigt werden, dass die Intensität sowohl die internen als auch der externen ökologischen Konnektivität durch die Hydrologie und Morphologie der Gewässer sowie durch die Verfügbarkeit von Nährstoffen wesentlich beeinflusst wird, die auf diese Weise vielfach die ökologische Funktionalität der Gewässer prägen. Dabei trägt die vertikale oder horizontale Konnektivität zur Stabilisierung der beteiligten Ökosysteme bei, indem sie den Austausch ermöglicht von Pflanzennährstoffen, von Biomasse sowie von migrierenden Organismen, wodurch Phasen des Ressourcenmangels überbrückt werden. Diese Ergebnisse können im Rahmen der Bewirtschaftung von Gewässern dahingehend genutzt werden, dass die Gewährleistung horizontaler und vertikaler Konnektivität in der Regel mit räumlich komplexeren, diverseren, zeitlich und strukturell resilienteren sowie leistungsfähi¬geren Ökosystemen einhergeht, die somit intensiver und sicherer nachhaltig genutzt werden können. Die Nutzung einer kleinen Auswahl von Ökosystemleistungen der Flüsse und Seen durch den Menschen hat oftmals zu einer starken Reduktion der ökologischen Konnektivität, und in der Folge zu starken Verlusten bei anderen Ökosystemleistungen geführt. Die Ergebnisse der dargestellten Forschungen zeigen auch, dass die Entwicklung und Implementierung von Strategien zum integrierten Management von komplexen sozial-ökologischen Systemen wesentlich unterstützt werden kann, wenn die horizontale und vertikale Konnektivität gezielt entwickelt wird. N2 - Surface waters are seen traditionally as closed ecosystems, and the recirculation of water and nutrients in the pelagic zone of lakes is cited as an example fort his. However, recently important linkages have been demonstrated between the pelagic zone on one side, and the benthic and the littoral zones, the terrestrial shore area and the catchment on the other side. Therby, the horizontal and vertical connectivity of aquatic ecosystems has attracted intense scientific interest, and together with this the ecological functions of the bottom zone (benthic zone) and of the shore zone (littoral zone), too. From this newly described connectivity far-reaching consequences arise for our picture of the functionality of surface waters. In this habilitation thesis a number of internal and external functional linkages are depicted in the horizontal and vertical spatial dimensions, as exemplified by running waters and lakes of the north-east German lowlands. The underlying studies mostly comprised both abiotic and biotic variables, and a broad range of topics, methods and studied surface waters. Thereby, experiments in the lab and the field, as well as quantitative field measurements were used to investigate ecological key processes as nutrient retention, carbon dynamics, extracellular enzyme activity, and resource transfer in food webs (using stabile isotope technique). In respect to running waters this resulted in substantial insights into the effects of a hydromorphology exhibiting intense connectivity on aquatic biodiversity and benthic-pelagic coupling, which represents a key process for the retention of transported matter, and thus for the productivity of a river section. The littoral zone of lakes has hardly been studied in Central Europe for several decades. Thus, the results on community structure, habitat preference and food web linkages of eulittoral macrozoobenthos enabled fundamentally new insights, which can directly be used within approaches for the ecological assessment of lake shores according to the EU Water Framework Directive. Research results show that the development and implementation of strategies for an integrated management of complex social-ecological systems may be substantially underpinned by targeted development of horizontal and vertical connectivity. KW - Limnology KW - Aquatic Ecology KW - Connectivity KW - Lake KW - River KW - Limnologie KW - Gewässerökologie KW - Konnektivität KW - See KW - Fluss Y1 - 2012 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-63713 ER - TY - JOUR A1 - Bernardez, Patricia A1 - Prego, Ricardo A1 - Virginia Filgueiras, Ana A1 - Ospina-Alvarez, Natalia A1 - Santos-Echeandia, Juan A1 - Angel Alvarez-Vazquez, Miguel A1 - Caetano, Miguel T1 - Lithogenic sources, composition and intra-annual variability of suspended particulate matter supplied from rivers to the Northern Galician Rias (Bay of Biscay) JF - Journal of sea research N2 - Scarce research about small European rivers from non-human impacted areas to determine their natural background state has been undertaken. During the annual hydrological cycle of 2008-9 the patterns of particulate supply (SPM, POC, PON, Al, Cd, Co, Cr, Cu, Fe, Ni, Pb, V, Zn) from the rivers Sor, Mera Landro, Lourido and Landoi to the Northern Galician Rias (SW Bay of Biscay) were tackled. No differences in the composition of the SPM were detected for the studied rivers regarding Al, Fe and POC but the relative percentage of particulate trace elements (PTE) discriminate the rivers. So, Cr, Co and Ni in the Lourido, and Landoi rivers, and Cu in the Mera River, are controlled by watershed minerals of Ortegal Geological Complex while for the rest rivers PTE are by granitic and Ollo de Sapo bedrock watershed. Therefore, the imprint of PTE in the parental rocks of the river basins is reflected on the coastal sediments of the Rias. The main process controlling the dynamics and variations of chemical elements in the particulate form is the river discharge. This fact exemplifies that these rivers presents a natural behavior not being highly influenced by anthropogenic activities. KW - SPM KW - Trace metals KW - Organic matter KW - River KW - W Cantabrian coast Y1 - 2017 U6 - https://doi.org/10.1016/j.seares.2017.05.006 SN - 1385-1101 SN - 1873-1414 VL - 130 SP - 73 EP - 84 PB - Elsevier CY - Amsterdam ER - TY - JOUR A1 - Purinton, Benjamin A1 - Bookhagen, Bodo T1 - Measuring decadal vertical land-level changes from SRTM-C (2000) and TanDEM-X (∼ 2015) in the south-central Andes JF - Earth Surface Dynamics N2 - In the arctic and high mountains it is common to measure vertical changes of ice sheets and glaciers via digital elevation model (DEM) differencing. This requires the signal of change to outweigh the noise associated with the datasets. Excluding large landslides, on the ice-free earth the land-level change is smaller in vertical magnitude and thus requires more accurate DEMs for differencing and identification of change. Previously, this has required meter to submeter data at small spatial scales. Following careful corrections, we are able to measure land-level changes in gravel-bed channels and steep hillslopes in the south-central Andes using the SRTM-C (collected in 2000) and the TanDEM-X (collected from 2010 to 2015) near-global 12–30m DEMs. Long-standing errors in the SRTM-C are corrected using the TanDEM-X as a control surface and applying cosine-fit co-registration to remove ∼ 1∕10 pixel (∼ 3m) shifts, fast Fourier transform (FFT) and filtering to remove SRTM-C short- and long-wavelength stripes, and blocked shifting to remove remaining complex biases. The datasets are then differenced and outlier pixels are identified as a potential signal for the case of gravel-bed channels and hillslopes. We are able to identify signals of incision and aggradation (with magnitudes down to ∼ 3m in the best case) in two  > 100km river reaches, with increased geomorphic activity downstream of knickpoints. Anthropogenic gravel excavation and piling is prominently measured, with magnitudes exceeding ±5m (up to  > 10m for large piles). These values correspond to conservative average rates of 0.2 to > 0.5myr−1 for vertical changes in gravel-bed rivers. For hillslopes, since we require stricter cutoffs for noise, we are only able to identify one major landslide in the study area with a deposit volume of 16±0.15×106m3. Additional signals of change can be garnered from TanDEM-X auxiliary layers; however, these are more difficult to quantify. The methods presented can be extended to any region of the world with SRTM-C and TanDEM-X coverage where vertical land-level changes are of interest, with the caveat that remaining vertical uncertainties in primarily the SRTM-C limit detection in steep and complex topography. KW - Digital Elevation Models KW - Glacier Mass Balances KW - Structure-from-motion KW - Accuracy Assessment KW - NW Argentina KW - Nevado Coropuna KW - Sediment Flux KW - Gravel-bed KW - River Y1 - 2018 U6 - https://doi.org/10.5194/esurf-6-971-2018 SN - 2196-6311 SN - 2196-632X VL - 6 SP - 971 EP - 987 PB - Copernicus Publ. CY - Göttingen ER - TY - GEN A1 - Purinton, Benjamin A1 - Bookhagen, Bodo T1 - Measuring decadal vertical land-level changes from SRTM-C (2000) and TanDEM-X (∼ 2015) in the south-central Andes T2 - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe N2 - In the arctic and high mountains it is common to measure vertical changes of ice sheets and glaciers via digital elevation model (DEM) differencing. This requires the signal of change to outweigh the noise associated with the datasets. Excluding large landslides, on the ice-free earth the land-level change is smaller in vertical magnitude and thus requires more accurate DEMs for differencing and identification of change. Previously, this has required meter to submeter data at small spatial scales. Following careful corrections, we are able to measure land-level changes in gravel-bed channels and steep hillslopes in the south-central Andes using the SRTM-C (collected in 2000) and the TanDEM-X (collected from 2010 to 2015) near-global 12–30m DEMs. Long-standing errors in the SRTM-C are corrected using the TanDEM-X as a control surface and applying cosine-fit co-registration to remove ∼ 1∕10 pixel (∼ 3m) shifts, fast Fourier transform (FFT) and filtering to remove SRTM-C short- and long-wavelength stripes, and blocked shifting to remove remaining complex biases. The datasets are then differenced and outlier pixels are identified as a potential signal for the case of gravel-bed channels and hillslopes. We are able to identify signals of incision and aggradation (with magnitudes down to ∼ 3m in the best case) in two  > 100km river reaches, with increased geomorphic activity downstream of knickpoints. Anthropogenic gravel excavation and piling is prominently measured, with magnitudes exceeding ±5m (up to  > 10m for large piles). These values correspond to conservative average rates of 0.2 to > 0.5myr−1 for vertical changes in gravel-bed rivers. For hillslopes, since we require stricter cutoffs for noise, we are only able to identify one major landslide in the study area with a deposit volume of 16±0.15×106m3. Additional signals of change can be garnered from TanDEM-X auxiliary layers; however, these are more difficult to quantify. The methods presented can be extended to any region of the world with SRTM-C and TanDEM-X coverage where vertical land-level changes are of interest, with the caveat that remaining vertical uncertainties in primarily the SRTM-C limit detection in steep and complex topography. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 480 KW - Digital Elevation Models KW - Glacier Mass Balances KW - Structure-from-motion KW - Accuracy Assessment KW - NW Argentina KW - Nevado Coropuna KW - Sediment Flux KW - Gravel-bed KW - River Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-420487 IS - 480 ER -