A Quantitative Graph-Based Approach to Monitoring Ice-Wedge Trough Dynamics in Polygonal Permafrost Landscapes
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Ingmar Nitze | Guido Grosse | Benjamin M. Jones | Johann-Christoph Freytag | Veit Helm | Moritz Langer | Tabea Rettelbach | J. Freytag | I. Nitze | M. Langer | G. Grosse | V. Helm | B. Jones | Tabea Rettelbach | Ingmar Nitze
[1] Guido Grosse,et al. Permafrost collapse is accelerating carbon release , 2019, Nature.
[2] Stuart N. Lane,et al. Connectivity as an emergent property of geomorphic systems , 2018, Earth Surface Processes and Landforms.
[3] V. Brovkin,et al. Expert assessment of vulnerability of permafrost carbon to climate change , 2013, Climatic Change.
[4] W. Baumgarten,et al. Detection, extraction, and analysis of the vein network of the slime mould Physarum polycephalum , 2010 .
[5] J. Fölster,et al. Predicting the depth and volume of lakes from map-derived parameters , 2011 .
[6] R. F. Black,et al. The Periglacial Environment , 1971 .
[7] Mathias Ulrich,et al. Polygon pattern geomorphometry on Svalbard (Norway) and western Utopia Planitia (Mars) using high-resolution stereo remote-sensing data , 2011 .
[8] Alexandru Onaca,et al. Assessment of Spatio-Temporal Landscape Changes from VHR Images in Three Different Permafrost Areas in the Western Russian Arctic , 2020, Remote. Sens..
[9] Guido Grosse,et al. Identification of unrecognized tundra fire events on the north slope of Alaska , 2013 .
[10] Guido Grosse,et al. Recent Arctic tundra fire initiates widespread thermokarst development , 2015, Scientific Reports.
[11] Milan Paluš,et al. Discerning connectivity from dynamics in climate networks , 2011 .
[12] M. Phillips,et al. Permafrost is warming at a global scale , 2019, Nature Communications.
[13] L. Larsen,et al. Directional connectivity in hydrology and ecology. , 2012, Ecological applications : a publication of the Ecological Society of America.
[14] Saskia Keesstra,et al. The way forward: Can connectivity be useful to design better measuring and modelling schemes for water and sediment dynamics? , 2018, The Science of the total environment.
[15] S. Lamoureux,et al. Effects of changing permafrost conditions on hydrological processes and fluvial fluxes , 2019, Earth-Science Reviews.
[16] T. Heckmann,et al. Graph theory in the geosciences , 2015 .
[17] Peter Schreiber,et al. Spatial and seasonal variability of polygonal tundra water balance: Lena River Delta, northern Siberia (Russia) , 2013, Hydrogeology Journal.
[18] M. Torn,et al. Isotopic insights into methane production, oxidation, and emissions in Arctic polygon tundra , 2016, Global change biology.
[19] Tazio Strozzi,et al. Thaw Subsidence of a Yedoma Landscape in Northern Siberia, Measured In Situ and Estimated from TerraSAR-X Interferometry , 2018, Remote. Sens..
[20] Voronoi Diagrams 9 . 1 Post Office Problem , 2022 .
[21] Hans Joosten,et al. Patterns in vegetation composition, surface height and thaw depth in polygon mires in the Yakutian Arctic (NE Siberia): a microtopographical characterisation of the active layer , 2009 .
[22] Joshua S. Weitz,et al. Leaf Extraction and Analysis Framework Graphical User Interface: Segmenting and Analyzing the Structure of Leaf Veins and Areoles1[W][OA] , 2010, Plant Physiology.
[23] Ning Zhang,et al. Analysis of Average Shortest-Path Length of Scale-Free Network , 2013, J. Appl. Math..
[24] V. Brovkin,et al. A stochastic model for the polygonal tundra based on Poisson–Voronoi diagrams , 2012 .
[25] Joshua C. Koch,et al. Lateral and subsurface flows impact arctic coastal plain lake water budgets , 2016 .
[26] Guido Grosse,et al. Size Distributions of Arctic Waterbodies Reveal Consistent Relations in Their Statistical Moments in Space and Time , 2019, Front. Earth Sci..
[27] P. Dutilleul,et al. Analysis of polygonal terrain landforms on Earth and Mars through spatial point patterns , 2009 .
[28] Guido Grosse,et al. Quantifying Wedge‐Ice Volumes in Yedoma and Thermokarst Basin Deposits , 2014 .
[29] U. Brandes. A faster algorithm for betweenness centrality , 2001 .
[30] Adam J. Heathcote,et al. Predicting bathymetric features of lakes from the topography of their surrounding landscape , 2015 .
[31] J. R. Mackay,et al. Some observations on the growth and deformation of epigenetic, syngenetic and anti‐syngenetic ice wedges , 2007 .
[32] Michael H. Young,et al. Brief communication: Rapid machine-learning-based extraction and measurement of ice wedge polygons in high-resolution digital elevation models , 2019, The Cryosphere.
[33] Wolfgang Schwanghart,et al. Graph theory-recent developments of its application in geomorphology , 2014 .
[34] Anna Liljedahl,et al. Pan-Arctic ice-wedge degradation in warming permafrost and its influence on tundra hydrology , 2016 .
[35] T. Heckmann,et al. Geomorphic coupling and sediment connectivity in an alpine catchment - exploring sediment cascades using graph theory , 2013 .
[36] J. Obu. How Much of the Earth's Surface is Underlain by Permafrost? , 2021, Journal of Geophysical Research: Earth Surface.
[37] Guido Grosse,et al. Estimated stocks of circumpolar permafrost carbon with quantified uncertainty ranges and identified data gaps , 2014 .
[38] Patrick M. Crill,et al. Methane dynamics regulated by microbial community response to permafrost thaw , 2014, Nature.
[39] Marcel Buchhorn,et al. Degradation and stabilization of ice wedges: Implications for assessing risk of thermokarst in northern Alaska , 2017 .
[40] B. Lehner,et al. Estimating the volume and age of water stored in global lakes using a geo-statistical approach , 2016, Nature Communications.
[41] M. Holland,et al. Polar amplification of climate change in coupled models , 2003 .
[42] Guido Grosse,et al. Quantifying landscape change in an arctic coastal lowland using repeat airborne LiDAR , 2013 .
[43] R. F. Black,et al. Periglacial Features Indicative of Permafrost: Ice and Soil Wedges , 1976, Quaternary Research.
[44] Jizhong Zhou,et al. Warming-induced permafrost thaw exacerbates tundra soil carbon decomposition mediated by microbial community , 2020, Microbiome.
[45] Franz Aurenhammer,et al. Voronoi Diagrams , 2000, Handbook of Computational Geometry.
[46] Boguslaw Obara,et al. A bioimage informatics approach to automatically extract complex fungal networks , 2012, Bioinform..
[47] Criticality and pattern formation in fracture by residual stresses. , 2010, Physical review. E, Statistical, nonlinear, and soft matter physics.
[48] R. Busey,et al. Seasonal and Interannual Ground-Surface Displacement in Intact and Disturbed Tundra along the Dalton Highway on the North Slope, Alaska , 2020, Land.
[49] Benjamin M. Jones,et al. An Object-Based Approach for Mapping Tundra Ice-Wedge Polygon Troughs from Very High Spatial Resolution Optical Satellite Imagery , 2021, Remote. Sens..
[50] Guido Grosse,et al. Changing permafrost in a warming world and feedbacks to the Earth system , 2016 .
[51] Dietmar J. Backes,et al. Multiscale Integration of High-Resolution Spaceborne and Drone-Based Imagery for a High-Accuracy Digital Elevation Model Over Tristan da Cunha , 2020, Frontiers in Earth Science.
[52] E. Addink,et al. Network concepts to describe channel importance and change in multichannel systems: test results for the Jamuna River, Bangladesh , 2014 .
[53] Chandana Gangodagamage,et al. Extrapolating active layer thickness measurements across Arctic polygonal terrain using LiDAR and NDVI data sets , 2014, Water resources research.
[54] D. M. Lawrence,et al. Climate change and the permafrost carbon feedback , 2014, Nature.
[55] Pedro Pina,et al. Evaluation of the use of very high resolution aerial imagery for accurate ice-wedge polygon mapping (Adventdalen, Svalbard). , 2017, The Science of the total environment.
[56] W. Pollard,et al. Impacts of Degrading Ice‐Wedges on Ground Temperatures in a High Arctic Polar Desert System , 2020, Journal of Geophysical Research: Earth Surface.
[57] Anastasios A. Tsonis,et al. Review article "On the origins of decadal climate variability: a network perspective" , 2012 .
[58] E. Pfeiffer,et al. Effect of microrelief and vegetation on methane emission from wet polygonal tundra, Lena Delta, Northern Siberia , 2004 .
[59] E. de K. Leffingwell,et al. Ground-Ice Wedges: The Dominant Form of Ground-Ice on the North Coast of Alaska , 1915, The Journal of Geology.
[60] Wilhelm Burger,et al. Digital Image Processing - An Algorithmic Introduction using Java , 2008, Texts in Computer Science.
[61] Wilfried Philips,et al. Quantitative analysis of venation patterns of Arabidopsis leaves by supervised image analysis. , 2012, The Plant journal : for cell and molecular biology.
[62] Rangasami L. Kashyap,et al. Building Skeleton Models via 3-D Medial Surface/Axis Thinning Algorithms , 1994, CVGIP Graph. Model. Image Process..
[63] J. Goździk,et al. Ice wedges: growth, thaw transformation, and palaeoenvironmental significance , 1988 .
[64] E. Foufoula‐Georgiou,et al. Dynamic connectivity in a fluvial network for identifying hotspots of geomorphic change , 2015 .
[65] S. Lamoureux,et al. The active layer: A conceptual review of monitoring, modelling techniques and changes in a warming climate , 2013 .
[66] Pierre Soille,et al. Morphological Image Analysis: Principles and Applications , 2003 .
[67] Chandi Witharana,et al. Use of Very High Spatial Resolution Commercial Satellite Imagery and Deep Learning to Automatically Map Ice-Wedge Polygons across Tundra Vegetation Types , 2020, J. Imaging.
[68] M. Langer,et al. Pathways of ice-wedge degradation in polygonal tundra under different hydrological conditions , 2018, The Cryosphere.
[69] K. Larson,et al. Decadal changes of surface elevation over permafrost area estimated using reflected GPS signals , 2017 .
[70] Weixing Zhang,et al. Deep Convolutional Neural Networks for Automated Characterization of Arctic Ice-Wedge Polygons in Very High Spatial Resolution Aerial Imagery , 2018, Remote. Sens..
[71] Julia Boike,et al. Environmental controls on CH4 emission from polygonal tundra on the microsite scale in the Lena river delta, Siberia , 2010 .
[72] Benjamin M. Jones,et al. Fire Behavior, Weather, and Burn Severity of the 2007 Anaktuvuk River Tundra Fire, North Slope, Alaska , 2009 .
[73] F. Hu,et al. Frequent Fires in Ancient Shrub Tundra: Implications of Paleorecords for Arctic Environmental Change , 2008, PloS one.
[74] Guido Grosse,et al. PeRL: a circum-Arctic Permafrost Region Pond and Lake database , 2016 .