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Regardless of political boundaries, river basins are a functional unit of the Earth’s land surface and provide an abundance of resources for the environment and humans. They supply livelihoods supported by the typical characteristics of large river basins, such as the provision of freshwater, irrigation water, and transport opportunities. At the same time, they are impacted i.e., by human-induced environmental changes, boundary conflicts, and upstream–downstream inequalities. In the framework of water resource management, monitoring of river basins is therefore of high importance, in particular for researchers, stake-holders and decision-makers. However, land surface and surface water properties of many major river basins remain largely unmonitored at basin scale. Several inventories exist, yet consistent spatial databases describing the status of major river basins at global scale are lacking. Here, Earth observation (EO) is a potential source of spatial information providing large-scale data on the status of land surface properties. This review provides a comprehensive overview of existing research articles analyzing major river basins primarily using EO. Furthermore, this review proposes to exploit EO data together with relevant open global-scale geodata to establish a database and to enable consistent spatial analyses and evaluate past and current states of major river basins.
Nationalparks sind das älteste und bekannteste flächenbezogene Naturschutzinstrument weltweit. Für den Erhalt einer nachhaltigen Lebensgrundlage und die Entwicklung der Biodiversität sowie für mehr Naturdynamik in der Landschaft haben sie eine sehr große Bedeutung, auch in unseren Breiten. Dennoch ist die Einstellung zu Nationalparks von Seiten der unmittelbaren Anwohner nicht immer unproblematisch. Entsprechend versucht die vorliegende wissenschaftliche Analyse neue Erkenntnisse bezüglich der Akzeptanz der Nationalparks Bayerischer Wald und Berchtesgaden, den ältesten Deutschlands, aufzuzeigen. Empirische Grundlagen für diese Studie sind eine bayernweite Online-Befragung, qualitative Experteninterviews und aufwändige repräsentative schriftliche Befragungen in den Nationalpark-Landkreisen Regen und Freyung-Grafenau bzw. Berchtesgadener Land im Jahr 2018. Auch die zeitliche Entwicklung der Akzeptanz wird auf Basis der Ergebnisse von Vorgängerstudien, soweit möglich, berücksichtigt. Dabei sind es ökonomische, emotionale, interpersonelle, soziokulturelle und nicht zuletzt für Geographen besonders interessante raumzeitliche Prädiktoren der Akzeptanz beider Nationalparks, die im Fokus der Untersuchungen stehen.
Air temperatures in the Arctic have increased substantially over the last decades, which has extensively altered the properties of the land surface. Capturing the state and dynamics of Land Surface Temperatures (LSTs) at high spatial detail is of high interest as LST is dependent on a variety of surficial properties and characterizes the land–atmosphere exchange of energy. Accordingly, this study analyses the influence of different physical surface properties on the long-term mean of the summer LST in the Arctic Mackenzie Delta Region (MDR) using Landsat 30 m-resolution imagery between 1985 and 2018 by taking advantage of the cloud computing capabilities of the Google Earth Engine. Multispectral indices, including the Normalized Difference Vegetation Index (NDVI), Normalized Difference Water Index (NDWI) and Tasseled Cap greenness (TCG), brightness (TCB), and wetness (TCW) as well as topographic features derived from the TanDEM-X digital elevation model are used in correlation and multiple linear regression analyses to reveal their influence on the LST. Furthermore, surface alteration trends of the LST, NDVI, and NDWI are revealed using the Theil-Sen (T-S) regression method. The results indicate that the mean summer LST appears to be mostly influenced by the topographic exposition as well as the prevalent moisture regime where higher evapotranspiration rates increase the latent heat flux and cause a cooling of the surface, as the variance is best explained by the TCW and northness of the terrain. However, fairly diverse model outcomes for different regions of the MDR (R2 from 0.31 to 0.74 and RMSE from 0.51 °C to 1.73 °C) highlight the heterogeneity of the landscape in terms of influential factors and suggests accounting for a broad spectrum of different factors when modeling mean LSTs. The T-S analysis revealed large-scale wetting and greening trends with a mean decadal increase of the NDVI/NDWI of approximately +0.03 between 1985 and 2018, which was mostly accompanied by a cooling of the land surface given the inverse relationship between mean LSTs and vegetation and moisture conditions. Disturbance through wildfires intensifies the surface alterations locally and lead to significantly cooler LSTs in the long-term compared to the undisturbed surroundings.
This study investigates synthetic aperture radar (SAR) time series of the Sentinel-1 mission acquired over the Atacama Desert, Chile, between March 2015 and December 2018. The contribution analyzes temporal and spatial variations of Sentinel-1 interferometric SAR (InSAR) coherence and exemplarily illustrates factors that are responsible for observed signal differences. The analyses are based on long temporal baselines (365–1090 days) and temporally dense time series constructed with short temporal baselines (12–24 days). Results are compared to multispectral data of Sentinel-2, morphometric features of the digital elevation model (DEM) TanDEM-X WorldDEM™, and to a detailed governmental geographic information system (GIS) dataset of the local hydrography. Sentinel-1 datasets are suited for generating extensive, nearly seamless InSAR coherence mosaics covering the entire Atacama Desert (>450 × 1100 km) at a spatial resolution of 20 × 20 meter per pixel. Temporal baselines over several years lead only to very minor decorrelation, indicating a very high signal stability of C-Band in this region, especially in the hyperarid uplands between the Coastal Cordillera and the Central Depression. Signal decorrelation was associated with certain types of surface cover (e.g., water or aeolian deposits) or with actual surface dynamics (e.g., anthropogenic disturbance (mining) or fluvial activity and overland flow). Strong rainfall events and fluvial activity in the periods 2015 to 2016 and 2017 to 2018 caused spatial patterns with significant signal decorrelation; observed linear coherence anomalies matched the reference channel network and indicated actual episodic and sporadic discharge events. In the period 2015–2016, area-wide loss of coherence appeared as strip-like patterns of more than 80 km length that matched the prevailing wind direction. These anomalies, and others observed in that period and in the period 2017–2018, were interpreted to be caused by overland flow of high magnitude, as their spatial location matched well with documented heavy rainfall events that showed cumulative precipitation amounts of more than 20 mm.
Sea level rise contribution from the Antarctic ice sheet is influenced by changes in glacier and ice shelf front position. Still, little is known about seasonal glacier and ice shelf front fluctuations as the manual delineation of calving fronts from remote sensing imagery is very time-consuming. The major challenge of automatic calving front extraction is the low contrast between floating glacier and ice shelf fronts and the surrounding sea ice. Additionally, in previous decades, remote sensing imagery over the often cloud-covered Antarctic coastline was limited. Nowadays, an abundance of Sentinel-1 imagery over the Antarctic coastline exists and could be used for tracking glacier and ice shelf front movement. To exploit the available Sentinel-1 data, we developed a processing chain allowing automatic extraction of the Antarctic coastline from Seninel-1 imagery and the creation of dense time series to assess calving front change. The core of the proposed workflow is a modified version of the deep learning architecture U-Net. This convolutional neural network (CNN) performs a semantic segmentation on dual-pol Sentinel-1 data and the Antarctic TanDEM-X digital elevation model (DEM). The proposed method is tested for four training and test areas along the Antarctic coastline. The automatically extracted fronts deviate on average 78 m in training and 108 m test areas. Spatial and temporal transferability is demonstrated on an automatically extracted 15-month time series along the Getz Ice Shelf. Between May 2017 and July 2018, the fronts along the Getz Ice Shelf show mostly an advancing tendency with the fastest moving front of DeVicq Glacier with 726 ± 20 m/yr.
Die hier vorgelegte geographisch-historische Abhandlung basiert auf dem Vergleich von zwei im zeitlichen Abstand von ca 60 Jahren (1958/59 = Dissertation und 2016/17 = wiederholendes Geländeprojekt) erfolgten Untersuchungen zum Verlauf und zum morphologischen Ergebnis von Bodenerosion nach akuten Starkregen sowie infolge schleichend-langfristiger Abspülung von Feinboden in verschiedenen Relieftypen des Taubertalgebietes. Alle Vorgänge der Bodenabtragung erfuhren erhebliche Differenzierung durch die unterschiedlichen Verfahren der landwirtschaftlichen Nutzung (z.B. Weinbau, Ackerbau,Viehhaltung). In zeitlichem Vergleich der einzelnen Lokalitäten und Fallstudien (Kartierung, Fotografie, Datenerfassung)konnte einerseits Abschwächung, andererseits Verstärkung der Bodenabspülung festgesetllt werden. Um längerfristig rückblickend die Wirkungsweise der flächen- u. linienhaften Bodenabtragung einzubeziehen, wurden historisch-archivalische Berichte über Folgen von Witterungsereignissen einbezogen und als Auswahl entsprechend der verschiedenen Bodennutzungsarten zusammengestellt. Diese Belege geben Aufschluss über historische Methoden und Techniken zur Verminderung erosionsbedingter Bodenverluste und damit zur Vermeidung existenzmindernder Ernteschäden. Mit diesem Rückblick ergaben sich auch Hinweise auf Phasen historisch-klimatisch veränderter Niederschlagsregime. Im Hinblick auf die durch den Klimawandel zu erwartende Zunahme der Starkregenanteile ergibt sich die Notwendigkeit, den Oberflächenabfluss von Regenmengen und damit deren Erosionskraft durch bodenschonende Nutzungsweisen zu verlangsamen.
In dieser Arbeit wird ein Verfahren zur Modellierung der Bodenerosion auf Ackerflächen in einem Untersuchungsgebiet im UNESCO-Biosphärenreservat Rhön vorgestellt. Als Grundlage dienen flächendeckend verfügbare, hochauflösende Datensätzen zu allen relevanten Faktoren. Ziel ist es die Sensitivität des Modells gegenüber verschiedenen Faktoren sowie die Übertragbarkeit des Verfahrens auf größere Untersuchungsgebiete zu testen. Die Modellierung findet dabei in ArcView 3.2 über die Extension AVErosion von SCHÄUBLE (2005) statt, während die Vorprozessierung in ArcMap von ESRI durchgeführt wird. Zunächst werden grundlegende Begriffe zu den Prozessen, Einflussfaktoren und Messmethoden von Bodenerosion erläutert. Die von Bodenerosion verursachten Schäden und mögliche Schutzmaßnahmen werden aufgrund ihrer Relevanz, unter anderem für die betroffenen Landwirte, geschildert. Nach dem Überblick über die wichtigsten Erosionsmodelle werden die hier verwendete Allgemeine Bodenabtragsgleichung (ABAG) und ihre einzelnen Berechnungsschritte vorgestellt. Das Modellierungstool AVErosion verwendet zusätzlich Elemente der Modified Universal Soil Loss Equation (MUSLE87). Zur Bodenerosionsmodellierung stehen hochauflösende Datensätze aus dem Untersuchungsgebiet zur Verfügung, aus denen in der Vorprozessierung die Raster der Faktoren errechnet werden. Insgesamt werden zehn Szenarien mit verschiedenen C-Faktoren und zwei Szenarien mit variierendem R-Faktor modelliert. Daraufhin wird das Untersuchungsgebiet nach physisch-geographischen Gesichtspunkten beschrieben und die landwirtschaftliche Nutzung in der Region charakterisiert. Die Ergebnisse der Modellierung zeigen, dass neben den Reliefeigenschaften die Bodenbewirtschaftung auf den Ackerflächen den größten Einfluss auf den Bodenabtrag hat. Die Variationen der Niederschlagssumme in den R-Faktor-Szenarien hat hingegen vergleichsweise wenig Auswirkungen auf das Modellierungsergebnis. Zwar konnte durch das Fehlen von aktuellen Bewirtschaftungsdaten keine Modellierung der tatsächlichen Bodenerosion erzielt werden, jedoch zeigen die verschiedenen C-Faktor-Szenarien den potentiellen Bodenabtrag bei unterschiedlicher Bewirtschaftung. Es wird deutlich, dass auf erosionsgefährdeten Flächen durch eine angepasste Form der landwirtschaftlichen Nutzung geringere Abtragswerte in der Modellierung erreicht werden können. Die Methode lässt sich gut auf das Untersuchungsgebiet im Biosphärenreservat Rhön anwenden und zeigt Potential zur Übertragung auf größere Untersuchungsgebiete
We analyze the processing of cereals and its role at Early Neolithic Göbekli Tepe, southeastern Anatolia (10th / 9th millennium BC), a site that has aroused much debate in archaeological discourse. To date, only zooarchaeological evidence has been discussed in regard to the subsistence of its builders. Göbekli Tepe consists of monumental round to oval buildings, erected in an earlier phase, and smaller rectangular buildings, built around them in a partially contemporaneous and later phase. The monumental buildings are best known as they were in the focus of research. They are around 20 m in diameter and have stone pillars that are up to 5.5 m high and often richly decorated. The rectangular buildings are smaller and–in some cases–have up to 2 m high, mostly undecorated, pillars. Especially striking is the number of tools related to food processing, including grinding slabs/bowls, handstones, pestles, and mortars, which have not been studied before. We analyzed more than 7000 artifacts for the present contribution. The high frequency of artifacts is unusual for contemporary sites in the region. Using an integrated approach of formal, experimental, and macro- / microscopical use-wear analyses we show that Neolithic people at Göbekli Tepe have produced standardized and efficient grinding tools, most of which have been used for the processing of cereals. Additional phytolith analysis confirms the massive presence of cereals at the site, filling the gap left by the weakly preserved charred macro-rests. The organization of work and food supply has always been a central question of research into Göbekli Tepe, as the construction and maintenance of the monumental architecture would have necessitated a considerable work force. Contextual analyses of the distribution of the elements of the grinding kit on site highlight a clear link between plant food preparation and the rectangular buildings and indicate clear delimitations of working areas for food production on the terraces the structures lie on, surrounding the circular buildings. There is evidence for extensive plant food processing and archaeozoological data hint at large-scale hunting of gazelle between midsummer and autumn. As no large storage facilities have been identified, we argue for a production of food for immediate use and interpret these seasonal peaks in activity at the site as evidence for the organization of large work feasts.
In recent years, the midlatitudes are characterized by more intense heatwaves in summer and sometimes severe cold spells in winter that might emanate from changes in atmospheric circulation, including synoptic‐scale and planetary wave activity in the midlatitudes. In this study, we investigate the heat and momentum exchange between the mean flow and atmospheric waves in the North Atlantic sector and adjacent continents by means of the physically consistent Eliassen–Palm flux diagnostics applied to reanalysis and forced climate model data. In the long‐term mean, momentum is transferred from the mean flow to atmospheric waves in the northwest Atlantic region, where cyclogenesis prevails. Further downstream over Europe, eddy fluxes return momentum to the mean flow, sustaining the jet stream against friction. A global climate model is able to reproduce this pattern with high accuracy. Atmospheric variability related to atmospheric wave activity is much more expressed at the intraseasonal rather than the interannual time‐scale. Over the last 40 years, reanalyses reveal a northward shift of the jet stream and a weakening of intraseasonal weather variability related to synoptic‐scale and planetary wave activity. This pertains to the winter and summer seasons, especially over central Europe, and correlates with changes in the North Atlantic Oscillation as well as regional temperature and precipitation. A very similar phenomenon is found in a climate model simulation with business‐as‐usual scenario, suggesting an anthropogenic trigger in the weakening of intraseasonal weather variability in the midlatitudes.
The alarming increase in the magnitude and spatiotemporal patterns of changes in composition, structure and function of forest ecosystems during recent years calls for enhanced cross-border mitigation and adaption measures, which strongly entail intensified research to understand the underlying processes in the ecosystems as well as their dynamics. Remote sensing data and methods are nowadays the main complementary sources of synoptic, up-to-date and objective information to support field observations in forest ecology. In particular, analysis of three-dimensional (3D) remote sensing data is regarded as an appropriate complement, since they are hypothesized to resemble the 3D character of most forest attributes. Following their use in various small-scale forest structural analyses over the past two decades, these sources of data are now on their way to be integrated in novel applications in fields like citizen science, environmental impact assessment, forest fire analysis, and biodiversity assessment in remote areas. These and a number of other novel applications provide valuable material for the Forests special issue “3D Remote Sensing Applications in Forest Ecology: Composition, Structure and Function”, which shows the promising future of these technologies and improves our understanding of the potentials and challenges of 3D remote sensing in practical forest ecology worldwide.