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Online Resource

Vorhabensbezeichnung: PermaSAR : Entwicklung einer Methode zur Detektion von Subsidenz in Permafrostgebieten mit D-InSAR : Schlussbericht : Laufzeit des Vorhabens: 01.04.2015-31.03.2019 (2019)

Antonova, Sofia [VerfasserIn]

[Heidelberg] : Ruprecht-Karls-Universität Heidelberg

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Keywords: Forschungsbericht ; Satellitenfernerkundung ; Radar ; Synthetische Apertur ; Interferometrie ; Dauerfrostboden ; Senkung

Type of Medium: Online Resource

Pages: 1 Online-Ressource (77 Seiten, 39,68 MB) , Illustrationen, Diagramme

URL: https://doi.org/10.2314/KXP:167848864X

DOI: 10.2314/KXP:167848864X

Language: German

Note: Förderkennzeichen BMWi 50EE1418 , Unterschiede zwischen dem gedruckten Dokument und der elektronischen Ressource können nicht ausgeschlossen werden

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Capturing complex star dune dynamics—repeated highly accurate surveys combining multitemporal 3D topographic measurements and local wind data (2022)

Herzog, Manuel ; Anders, Katharina ; Höfle, Bernhard ; [et al.]

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Publication Date: 2022-10-06

Description: Morphologies of highly complex star dunes are the result of aeolian dynamics in past and present times. These dynamics reflect climatic conditions and associated forces like sediment availability and vegetation cover, as well as feedbacks with adjacent environments. However, an understanding of aeolian dynamics on star dune morphometries is still lacking sufficient detail, and their influence on formation and evolution remains unclear. We therefore investigate the dynamics of a complex star dune (Erg Chebbi, Morocco) by analysing wind measurements compared to morphometric changes derived from multitemporal high‐accuracy 3D observations during two surveys (October 2018 and February 2020). Using real‐time kinematic global navigation satellite system (RTK‐GNSS) measurements and terrestrial laser scanning (TLS), the reaction of a star dune surface to an observed constant unimodal sand‐moving wind is presented. TLS point clouds are used for morphometric analysis as well as direct surface change analysis, which relates to sand transport. RTK‐GNSS measurements enable the assessment of horizontal crest movement. Observed surface changes lead to the identification of an overall shielding effect, resulting in sand accumulation mainly on windward slopes. Our results point to a self‐sustained dune growth, which has not yet been described in such spatial detail. Steep slopes, often found on star dunes around the globe, seem to partly hinder upslope sand transport. Though a comparatively short observation period, we therefore hypothesize that, besides wind intensity alone, slope angles are more decisive for sand transport than previously assumed. Our methodological approach of combining meteorological data and high‐resolution multitemporal 3D elevation models can be used for monitoring all dune forms and contributes to a general understanding of dune dynamics and evolution.

Description: The accurate detection of altitudinal surface changes on a star dune compared to climatic data enables the identification of aeolian dynamics and new mechanisms where, besides wind intensity alone, slope angles are more decisive for sand transport than previously assumed. The methodological approach can be transferred to all dune forms, ranging from small barchans to complex and extensive star dunes.

Description: https://doi.org/10.11588/data/ZAMGCL

Keywords: ddc:551.37

Language: English

Type: doc-type:article

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3

Electronic Resource

Accelerated Radiotherapy with Concomitant ACNU/Ara-C for the Treatment of Malignant Glioma (2000)

Anders, Katharina ; Grabenbauer, Gerhard G. ; Schuchardt, Ulrike ; [et al.]

Springer

Journal of neuro-oncology 48 (2000), S. 63-73

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ISSN: 1573-7373

Keywords: accelerated radiation therapy ; ACNU ; Ara-C ; chemotherapy ; high-grade glioma

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Purpose To evaluate activity and toxicity of simultaneous ACNU and Ara-C with concurrent accelerated hyperfractionated radiotherapy in the treatment of high-grade glioma. Patients and Methods Thirty patients aged 23–71 years (median 47.5), 16 patients with glioblastoma multiforme (GBM) and 14 patients with grade-III glioma, received 93 courses of ACNU/Ara-C (median 4 courses) at following dose levels (ACNU/Ara-C in mg/m2/day): 70/90 (11 courses), 75/100 (36 courses) and 90/120 (46 courses). ACNU was administered IV on day 1 of each cycle, Ara-C as a 2 h-intravenous infusion on days 1–3. Patients received concomitant radiation therapy with 2 daily fractions of 1.75 Gy up to 57 Gy (median). Results Median survival of all patients was 13 months, 11 months for GBM and 〉 28 months for grade-III glioma; 31% (9 patients) survived longer than 24 months. The percentage of grade IV hematological toxicity was dose-dependent: 33% at the 70/90 dose level, 40% at 75/100 and 58% at 90/120. Six patients required platelet transfusion, 1 patient red blood cells; no febrile neutropenia occurred. Among 18 patients evaluable for response, 3 (17%) showed PR, 8 (44%) NC and 7 (39%) PD at completion of chemoradiation. No acute or late neurological toxicity occurred in this study. Younger age (p = 0.0001) and grade-III histology (p = 0.0009) were important prognostic factors for prolonged survival. Conclusion This chemoradiation regimen is active in malignant gliomas and can be safely recommended at a dose level using 70 mg/m2 ACNU together with 90 mg/m2 Ara-C.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1006498525605

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Terrestrial laser scanning for quantifying small-scale vertical movements of the ground surface in Arctic permafrost regions (2017)

Marx, Sabrina ; Anders, Katharina ; Antonova, Sofia ; [et al.]

In: EPIC3ARCTIC CHANGE 2017, Québec, Canada, 2017-12-12-2017-12-15

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Publication Date: 2018-01-19

Description: Three-dimensional data acquired by terrestrial laser scanning (TLS) provides an accurate representation of the Earth’s surface, which is commonly used to detect and quantify topographic changes on a small scale. However, in Arctic permafrost regions TLS-based monitoring of thaw subsidence is challenging due to vegetation and the micro-topographic characteristics (e.g. dense moss-lichen layer, hummocks etc.). In this presentation, we focus, firstly, on the evaluation of raster- and point-based TLS methods for quantifying small-scale thaw subsidence within the continuous permafrost zone. Secondly, a new filter strategy is presented that reduces spatial sampling effects caused by various factors such as vegetation, micro-topography and scan-setup. Our study site is located at the Trail Valley Creek research watershed, 50 km north-east of Inuvik, Northwest Territories, Canada. Three field campaigns took place in 2015 and 2016. Besides capturing TLS data, at-point real-time kinematic (RTK) Global Navigation Satellite System (GNSS) measurements and manual subsidence measurements were gathered. To achieve a highly accurate registration (on mm-scale) of the three TLS campaigns, co-registration of the georeferenced point clouds is performed based on the stable fix points in the otherwise highly dynamic permafrost environment. Then, different methods to quantify vertical ground movements are applied and evaluated. The result reveals limitations of standard raster-based DEM differencing, but also of point-based distance calculation for detecting spatial patterns of small-scale thaw subsidence. In the Arctic tundra ecosystem, TLS-based deformation analysis is strongly affected by occlusion and spatial sampling effects, even if data acquisition is repeated from similar scan positions. We show that the mentioned errors can be reduced by capturing the ground surface from more than one TLS scan position. Our filter strategy allows to identify TLS points which are suitable for multi-temporal deformation analyses, and results in an average seasonal subsidence rate (2015/06-2015/08) of about -2.0 cm at our study site. The derived subsidence maps deliver highly accurate ground-truth data, which is needed to improve area-wide subsidence monitoring methods such as SAR interferometry. This leads to a deeper understanding of permafrost-related subsidence processes.

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , notRev

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Estimation of forest properties in the treeline zone using TanDEM-X and airborne laser scanning data (2018)

Antonova, Sofia ; Thiel, Christian ; Höfle, Bernhard ; [et al.]

Bibliothek Wissenschaftspark Albert Einstein

In: EPIC315th International Circumpolar Remote Sensing Symposium, Potsdam, Germany, 2018-09-10-2018-09-14Potsdam, Germany, Bibliothek Wissenschaftspark Albert Einstein

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Publication Date: 2018-09-24

Description: Northward shift of the treeline is expected circum-Arctic and has been observed in a number of locations in response to Arctic warming. The transitional zone between forest and tundra is, therefore, a vulnerable region that requires systematic monitoring. Currently, radar remote sensing is hardly employed in the treeline zone. The unique constellation of the TanDEM-X satellites with its bistatic mode and unprecedented spatial resolution opens new opportunities for monitoring of the treeline zone. We focus on an area near the Trail Valley Creek research basin in the east of the Mackenzie Delta in the Northwest Territories, Canada. The area lies at the northern edge of the treeline zone. Erect vegetation there is characterised by deciduous shrubs up to 3 m in height and isolated patches of sparse coniferous forest. We evaluate the potential of TanDEM-X bistatic data to characterise the structural properties of the forest patches. The TanDEM-X data were acquired during the TanDEM-X Science Phase in 2015, when the effective baseline was large and constant (approximately 540 m). We employ interferometric coherence from multitemporal bistatic pairs and compare it with standard vegetation metrics obtained from airborne LiDAR data. The full-waveform airborne LiDAR data were captured in September 2016, covering an area of about 20 km x 6 km with a point density of approximately 5 points per square meter. LiDAR metrics include vegetation height percentiles and vegetation ratio. The preliminary analysis shows a high agreement between TanDEM-X bistatic coherence and LiDAR vegetation metrics. The relation between coherence and LiDAR metrics, averaged for each forest patch, yields in a strong inverse correlation, varying from -0.81 to -0.88 for different LiDAR metrics. On sub- atch scale, spatial patterns of coherence and LiDAR metrics also show high inverse correspondence. Thus, a pixel-by-pixel comparison gives a first-shot correlation between tree height 99 percentile and coherence from -0.45 to -0.63 for different forest patches. Taking into account the global coverage of multiple bistatic TanDEM-X data acquired for the global digital elevation model, our results provide a basis for the quantification of the treeline properties circum-Arctic.

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , notRev

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PermaSAR : Entwicklung einer Methode zur Detektion von Subsidenz in Permafrostgebieten mit D-InSAR : Schlussbericht (2019)

Antonova, Sofia ; Beck, Inga ; Marx, Sabrina ; [et al.]

TIB

In: EPIC3TIB, 77 p.

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Publication Date: 2019-10-22

Description: Etwa ein Viertel der nördlichen Hemisphäre ist von dauerhaft gefrorenem Boden, dem Permafrost, geprägt. Im Sommer taut die oberste Schicht des Permafrostes auf und gefriert im Winter wieder. Durch die starke Erwärmung des arktischen Klimas taut der Boden im Sommer tiefer auf als bisher. In südlichen Gebieten der Arktis kommt Permafrost nur noch vereinzelt vor (diskontinuierlich oder sporadisch). Durch die Erwärmung kann Permafrost in diesen Gebieten sogar komplett verschwinden. Wenn Permafrost im Sommer auftaut, schmilzt das im Boden gespeicherte Eis. Dadurch verringert sich das Bodenvolumen und die Landoberfläche senkt sich in vielen Gebieten der Arktis. Zwar findet während der Gefrierperiode oftmals wieder eine Hebung statt. Jedoch konnte in den vergangenen Jahren in einigen Gebieten eine Nettosenkung - auch Subsidenz genannt - beobachtet werden. Diese ist auf die ansteigenden Temperaturen und die damit verbundenen höheren Auftauraten zurückzuführen. Das verstärkte Tauen des Permafrostbodens hat schwerwiegende Folgen für Ökosysteme, Infrastruktur und die ansässige Bevölkerung mit sich. Es ist daher sowohl für die Wissenschaft, als auch für Wirtschaft und Politik essentiell, diese Vorgänge quantifizieren zu können.

Repository Name: EPIC Alfred Wegener Institut

Type: Miscellaneous , notRev

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Estimation of forest properties in a treeline zone using TanDEM-X and airborne laser scanning data (2018)

Antonova, Sofia ; Höfle, Bernhard ; Thiel, Christian ; [et al.]

Laboratoire EDYTEM - UMR5204 Université Savoie Mont Blanc

In: EPIC35th European Conference on Permafrost (EUCOP 2018), Chamonix, France, 2018-06-23-2018-07-01Le Bourget du Lac, France, Laboratoire EDYTEM - UMR5204 Université Savoie Mont Blanc

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Publication Date: 2018-09-24

Description: The high-latitude forest-tundra transitional zone is a region which is highly vulnerable to the current Arctic warming. The local changes accompanying expected northward migration of the treeline requires systematic monitoring. We focus on an area in the east of the Mackenzie Delta in Northwest Territories, Canada, which is characterised by patches of black spruce forest. We investigate the capability of TerraSAR-X / TanDEM-X bistatic constellation for the characterisation of these forest patches. Interferometric phase and coherence from seven image pairs were used to estimate tree height and density. We compare the SAR products with standard vegetation metrics from airborne LiDAR, such as vegetation height percentiles and vegetation ratio. The preliminary analysis shows a high agreement between SAR and LiDAR data.

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , notRev

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Multitemporal terrestrial laser scanning point clouds for thaw subsidence observation at Arctic permafrost monitoring sites (2021)

Anders, Katharina ; Marx, Sabrina ; Boike, Julia ; [et al.]

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Publication Date: 2021-07-04

Description: This paper investigates different methods for quantifying thaw subsidence using terrestrial laser scanning (TLS) point clouds. Thaw subsidence is a slow (millimetre to centimetre per year) vertical displacement of the ground surface common in ice‐rich permafrost‐underlain landscapes. It is difficult to quantify thaw subsidence in tundra areas as they often lack stable reference frames. Also, there is no solid ground surface to serve as a basis for elevation measurements, due to a continuous moss–lichen cover. We investigate how an expert‐driven method improves the accuracy of benchmark measurements at discrete locations within two sites using multitemporal TLS data of a 1‐year period. Our method aggregates multiple experts’ determination of the ground surface in 3D point clouds, collected in a web‐based tool. We then compare this to the performance of a fully automated ground surface determination method. Lastly, we quantify ground surface displacement by directly computing multitemporal point cloud distances, thereby extending thaw subsidence observation to an area‐based assessment. Using the expert‐driven quantification as reference, we validate the other methods, including in‐situ benchmark measurements from a conventional field survey. This study demonstrates that quantifying the ground surface using 3D point clouds is more accurate than the field survey method. The expert‐driven method achieves an accuracy of 0.1 ± 0.1 cm. Compared to this, in‐situ benchmark measurements by single surveyors yield an accuracy of 0.4 ± 1.5 cm. This difference between the two methods is important, considering an observed displacement of 1.4 cm at the sites. Thaw subsidence quantification with the fully automatic benchmark‐based method achieves an accuracy of 0.2 ± 0.5 cm and direct point cloud distance computation an accuracy of 0.2 ± 0.9 cm. The range in accuracy is largely influenced by properties of vegetation structure at locations within the sites. The developed methods enable a link of automated quantification and expert judgement for transparent long‐term monitoring of permafrost subsidence. © 2020 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd

Description: This paper investigates methods using terrestrial laser scanning point clouds for quantifying thaw subsidence in permafrost‐underlain tundra fully automatically and by including information collected from expert analysts. Results of the developed methods achieve higher accuracies compared to manual in‐situ measurements, which are found to vary from reference measurements in the magnitude of the actual ground surface displacement observed in a 1‐year period. A link of automated quantification and expert judgement can enable transparent long‐term monitoring of thaw subsidence.

Description: German Federal Ministry of Economics and Technology (BMWi) and German Aerospace Center (DLR)

Description: Heidelberg Graduate School of Mathematical and Computational Methods for the Sciences, University of Heidelberg http://dx.doi.org/10.13039/501100003801

Description: Federal Ministry of Economics and Technology (BMWi) and the German Aerospace Centre (DLR), Germany http://dx.doi.org/10.13039/501100002765

Keywords: 551 ; change analysis ; 3D geoinformation ; ground surface displacement ; permafrost monitoring ; multitemporal LiDAR

Type: article

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Bistatic coherence from CoSSC TanDEM-X data for tree height estimation in the Canadian Subarctic (2017)

Antonova, Sofia ; Anders, Katharina ; Helm, Veit ; [et al.]

In: EPIC35th HGF Alliance “Remote Sensing and Earth System Dynamics” Week, 2017-06-26-2017-06-30

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Publication Date: 2017-10-17

Repository Name: EPIC Alfred Wegener Institut

Type: Conference , notRev

Format: application/pdf

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A 16-year record (2002–2017) of permafrost, active-layer, and meteorological conditions at the Samoylov Island Arctic permafrost research site, Lena River delta, northern Siberia: an opportunity to validate remote-sensing data and land surface, snow, and permafrost models (2019)

Boike, Julia ; Nitzbon, Jan ; Anders, Katharina ; [et al.]

In: EPIC3Earth System Science Data, 11(1), pp. 261-299, ISSN: 1866-3516

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Publication Date: 2021-08-16

Description: Most of the world's permafrost is located in the Arctic, where its frozen organic carbon content makes it a potentially important influence on the global climate system. The Arctic climate appears to be changing more rapidly than the lower latitudes, but observational data density in the region is low. Permafrost thaw and carbon release into the atmosphere, as well as snow cover changes, are positive feedback mechanisms that have the potential for climate warming. It is therefore particularly important to understand the links between the energy balance, which can vary rapidly over hourly to annual timescales, and permafrost conditions, which changes slowly on decadal to centennial timescales. This requires long-term observational data such as that available from the Samoylov research site in northern Siberia, where meteorological parameters, energy balance, and subsurface observations have been recorded since 1998. This paper presents the temporal data set produced between 2002 and 2017, explaining the instrumentation, calibration, processing, and data quality control. Furthermore, we present a merged data set of the parameters, which were measured from 1998 onwards. Additional data include a high-resolution digital terrain model (DTM) obtained from terrestrial lidar laser scanning. Since the data provide observations of temporally variable parameters that influence energy fluxes between permafrost, active-layer soils, and the atmosphere (such as snow depth and soil moisture content), they are suitable for calibrating and quantifying the dynamics of permafrost as a component in earth system models. The data also include soil properties beneath different microtopographic features (a polygon centre, a rim, a slope, and a trough), yielding much-needed information on landscape heterogeneity for use in land surface modelling. For the record from 1998 to 2017, the average mean annual air temperature was −12.3 ∘C, with mean monthly temperature of the warmest month (July) recorded as 9.5 ∘C and for the coldest month (February) −32.7 ∘C. The average annual rainfall was 169 mm. The depth of zero annual amplitude is at 20.75 m. At this depth, the temperature has increased from −9.1 ∘C in 2006 to −7.7 ∘C in 2017. The presented data are freely available through the PANGAEA (https://doi.org/10.1594/PANGAEA.891142) and Zenodo (https://zenodo.org/record/2223709, last access: 6 February 2019) websites.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

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