Mapping Glacier Forelands Based on UAV BVLOS Operation in Antarctica

The aim of this article is to show geomorphological mapping of remote Antarctic locations using images taken by a fixed-wing unmanned aerial vehicle (UAV) during the Beyond Visual Line of Sight (BVLOS) operations. We mapped landform assemblages developed in forelands of Ecology Glacier (EGF), Sphinx Glacier (SGF) and Baranowski Glacier (BGF) in Antarctic Specially Protected Area No. 128 (ASPA 128) on King George Island (South Shetland Islands) and inferred about glacial dynamics. The orthophoto and digital elevation model allowed for geomorphological mapping of glacial forelands, including (i) glacial depositional landforms, (ii) fluvial and fluvioglacial landforms, (iii) littoral and lacustrine landforms, (iv) bodies of water, and (v) other. The largest area is occupied by ground moraine and glacial lagoons on EGF and BGF. The most profound features of EGF are the large latero-frontal moraine ridges from Little Ice Age and the first half of the 20th century. Large areas of ground moraine, frequently fluted and marked with large recessional moraine ridges, dominate on SGF. A significant percentage of bedrock outcrops and end moraine complexes characterize BGF. The landform assemblages are typical for discontinuous fast ice flow of tidewater glaciers over a deformable bed. It is inferred that ice flow velocity decreased as a result of recession from the sea coast, resulting in a significant decrease in the length of ice cliffs and decrease in calving rate. Image acquisition during the fixed-wing UAV BVLOS operation proved to be a very robust technique in harsh polar conditions of King George Island.

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Seafloor geomorphology of western Antarctic Peninsula bays: a signature of ice flow behaviour

The Cryosphere ◽

10.5194/tc-12-205-2018 ◽

2018 ◽

Vol 12 (1) ◽

pp. 205-225 ◽

Cited By ~ 3

Author(s):

Yuribia P. Munoz ◽

Julia S. Wellner

Keyword(s):

Antarctic Peninsula ◽

Numerical Models ◽

Ice Age ◽

South Shetland Islands ◽

Schematic Model ◽

Western Antarctic Peninsula ◽

Ice Flow ◽

Swath Bathymetry ◽

Glacial Dynamics ◽

Submarine Landforms

Abstract. Glacial geomorphology is used in Antarctica to reconstruct ice advance during the Last Glacial Maximum and subsequent retreat across the continental shelf. Analogous geomorphic assemblages are found in glaciated fjords and are used to interpret the glacial history and glacial dynamics in those areas. In addition, understanding the distribution of submarine landforms in bays and the local controls exerted on ice flow can help improve numerical models by providing constraints through these drainage areas. We present multibeam swath bathymetry from several bays in the South Shetland Islands and the western Antarctic Peninsula. The submarine landforms are described and interpreted in detail. A schematic model was developed showing the features found in the bays: from glacial lineations and moraines in the inner bay to grounding zone wedges and drumlinoid features in the middle bay and streamlined features and meltwater channels in the outer bay areas. In addition, we analysed local variables in the bays and observed the following: (1) the number of landforms found in the bays scales to the size of the bay, but the geometry of the bays dictates the types of features that form; specifically, we observe a correlation between the bay width and the number of transverse features present in the bays. (2) The smaller seafloor features are present only in the smaller glacial systems, indicating that short-lived atmospheric and oceanographic fluctuations, responsible for the formation of these landforms, are only recorded in these smaller systems. (3) Meltwater channels are abundant on the seafloor, but some are subglacial, carved in bedrock, and some are modern erosional features, carved on soft sediment. Lastly, based on geomorphological evidence, we propose the features found in some of the proximal bay areas were formed during a recent glacial advance, likely the Little Ice Age.

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A new Antarctic foraminiferal species for detecting climate change in sub-Recent glacier-proximal sediments

Antarctic Science ◽

10.1017/s0954102009990150 ◽

2009 ◽

Vol 21 (5) ◽

pp. 439-448 ◽

Cited By ~ 10

Author(s):

Wojciech Majewski ◽

Andrzej Tatur

Keyword(s):

Climate Change ◽

Climate Warming ◽

The Arctic ◽

South Shetland Islands ◽

King George Island ◽

Tidewater Glaciers ◽

Admiralty Bay ◽

Shetland Islands ◽

Foraminiferal Species ◽

Water Depths

AbstractCribroelphidium webbi sp. nov. is the only adequately described sub-Recent elphidiid foraminifer from Antarctica. In Admiralty Bay (King George Island, South Shetland Islands), it is found at several locations within inner fiord setting at water depths between 33 and 165 m, but most commonly shallower than 100 m. In outer basins this foraminifer is absent. In the cores analysed, C. webbi sp. nov. is present in well-constrained sub-Recent horizons that are clearly related to climate warming and deglaciation. These horizons represent a diachronous facies marker rather than a single stratigraphic layer. Cribroelphidium webbi sp. nov. shows clear association with retreating tidewater glaciers, therefore it is an important sensitive glacier-proximal indicator. It appears that it shares similar ecologic affinities with Cribroelphidium excavatum clavatum, which is widely distributed throughout the Arctic.

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Recent, rapid and profound changes to glacier morphology and dynamics, Juneau Icefield, Alaska

10.5194/egusphere-egu21-1539 ◽

2021 ◽

Author(s):

Bethan Davies ◽

Jacob Bendle ◽

Robert McNabb ◽

Jonathan Carrivick ◽

Christopher McNeil ◽

...

Keyword(s):

Little Ice Age ◽

Ice Age ◽

Aerial Photographs ◽

Equilibrium Line Altitude ◽

Regional Warming ◽

Geomorphological Mapping ◽

Glacier Recession ◽

Digital Elevation ◽

High Resolution Satellite Imagery ◽

Global Sea Level

The Alaskan region (comprising glaciers in Alaska, British Columbia and Yukon) contains the third largest ice volume outside of the Greenland and Antarctic ice sheets, and contributes more to global sea level rise than any other glacierised region defined by the Randolph Glacier Inventory. However, ice loss in this area is not linear, but in part controlled by glacier hypsometry as valley and outlet glaciers are at risk of becoming detached from their accumulation areas during thinning. Plateau icefields, such as Juneau Icefield in Alaska, are very sensitive to changes in Equilibrium Line Altitude (ELA) as this can result in rapidly shrinking accumulation areas. Here, we present detailed geomorphological mapping around Juneau Icefield and use this data to reconstruct the icefield during the &#8220;Little Ice Age&#8221;. We use topographic maps, archival aerial photographs, high-resolution satellite imagery and digital elevation models to map glacier lake and glacier area and volume change from the Little Ice Age to the present day (1770, 1948, 1979, 1990, 2005, 2015 and 2019 AD). Structural glaciological mapping (1979 and 2019) highlights structural and topographic controls on non-linear glacier recession.&#160; Our data shows pronounced glacier thinning and recession in response to widespread detachment of outlet glaciers from their plateau accumulation areas. Glacier detachments became common after 2005, and occurred with increasing frequency since then. Total summed rates of area change increased eightfold from 1770-1948 (-6.14 km2 a-1) to 2015-2019 (-45.23 km2 a-1). Total rates of recession were consistent from 1770 to 1990 AD, and grew increasingly rapid after 2005, in line with regional warming.

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Mapping glaciers in Jotunheimen, South-Norway, during the "Little Ice Age" maximum

The Cryosphere ◽

10.5194/tc-3-231-2009 ◽

2009 ◽

Vol 3 (2) ◽

pp. 231-243 ◽

Cited By ~ 21

Author(s):

S. Baumann ◽

S. Winkler ◽

L. M. Andreassen

Keyword(s):

Little Ice Age ◽

18Th Century ◽

Field Measurements ◽

Geographical Information ◽

Ice Age ◽

Inventory Data ◽

Digital Elevation ◽

Remote Sensing Techniques ◽

Southern Norway ◽

Elevation Model

Abstract. The maximum glacier extent during the "Little Ice Age" (mid 18th century AD) in Jotunheimen, southern Norway, was mapped using remote sensing techniques. Interpretation of existing glaciochronological studies, analysis of geomorphological maps, and own GPS-field measurements were applied for validation of the mapping. The length of glacier centrelines and other inventory data were determined using a Geographical Information System (GIS) and a Digital Elevation Model. "Little Ice Age" maximum extent for a total of 233 glaciers comprising an overall glacier area of about 290 km2 was mapped. Mean length of the centreline was calculated to 1.6 km. Until AD 2003, the area and length shrank by 35% and 34%, respectively, compared with the maximum "Little Ice Age" extent.

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Distribución espacial y temporal de glaciares, glaciares cubiertos y glaciares rocosos durante la última deglaciación en el valle de La Bonaigua (Pirineo Central)

Cuadernos de Investigación Geográfica ◽

10.18172/cig.4395 ◽

2020 ◽

Vol 46 (2) ◽

pp. 413-446

Author(s):

J. Ventura-Roca

Keyword(s):

High Resolution ◽

Little Ice Age ◽

Ice Age ◽

Lidar Data ◽

Forest Environment ◽

Digital Elevation ◽

Rock Glaciers ◽

Elevation Model ◽

Glacial Landforms ◽

Central Pyrenees

The application of the paleogeographic method to the study of glacial landforms and rock glaciers allows their morphometric and sedimentological characterization, the establishment of a detailed morphostratigraphic sequence and a chronological proposal for the identified glacial phases. This study analyzes 86 landforms (57 glacial deposits, 21 rock glaciers and 8 protalus ramparts) in the Bonaigua Valley (Noguera Pallaresa Basin, Central Pyrenees), with special attention to the differentiation between debris-covered glaciers and rock glaciers. Other subjects studied concerning rock glaciers are: distinguish its glacial or periglacial origin; the possible current activity of some landforms, and the detection of rock glaciers located at low altitudes (in the current forest environment) through the use of high-resolution digital elevation model (2x2 m) from LIDAR data. The chronological hypothesis elaborated by correlation with other high Pyrenean valleys (with absolute ages available) includes 7 phases (6 glacial phases and 1 periglacial phase) in which co-exist and/or evolve, in a paraglacial dynamic, glaciers, debris-covered glaciers and rock glaciers, and that we temporarily place between the end of the Oldest Dryas and the Little Ice Age.

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The late Quaternary stratigraphic record northwest of Montréal: regional ice-sheet dynamics, ice-stream activity, and early deglacial events

Canadian Journal of Earth Sciences ◽

10.1139/e05-118 ◽

2006 ◽

Vol 43 (4) ◽

pp. 461-485 ◽

Cited By ~ 19

Author(s):

Martin Ross ◽

Michel Parent ◽

Beatriz Benjumea ◽

James Hunter

Keyword(s):

Late Quaternary ◽

Late Glacial ◽

Ice Flow ◽

Glacial Sediments ◽

Ice Stream ◽

Digital Elevation ◽

Flow Features ◽

Ice Sheet Dynamics ◽

Late Wisconsinan ◽

Elevation Model

The Quaternary sediments of previously unstudied buried valleys and sections near Montréal are analyzed and other sites are revisited to further develop the stratigraphic framework of the St. Lawrence Lowland and to establish regional glacial and deglacial models. The southwest-trending buried valleys were investigated by stratigraphic drilling and high-resolution seismic profiling. The Quaternary succession consists, from base to top, of proximal glaciolacustrine sediments, two superposed till sheets (Argenteuil and Oka tills) of inferred Late Wisconsinan age, and Champlain Sea sediments. The glacial sediments of this sequence record an ice advance toward south (Argenteuil Till) followed by an abrupt ice-flow shift toward the southwest (Oka Till). Compositional and geomorphic data indicate that Oka Till is ubiquitous and is associated with a regional set of glacial landforms. The analysis of a regional digital elevation model in combination with published ice-flow indicators shows convergent flow patterns from the OttawaMontréalAdirondack regions toward the Lake Ontario basin. Landforms produced by the inferred ice stream are locally crosscut by southward-trending ice-flow features. Hence southward flow in the upper St. Lawrence Valley seemingly took place in two distinct contexts: (1) during full glacial conditions, as ice margins stood at or near the late glacial maximum limits, and (2) during late deglaciation, as a post-ice stream reequilibration mechanism. Early deglacial events in the study area were also characterized by subglacial meltwater channelling and erosion along the valleys, subaquatic outwash deposition in glacial Lake Candona, and rapid infill of the valleys during the early stages of the ensuing Champlain Sea.

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21st-century increase in glacier mass loss in the Wrangell Mountains, Alaska, USA, from airborne laser altimetry and satellite stereo imagery

Journal of Glaciology ◽

10.3189/2014jog13j119 ◽

2014 ◽

Vol 60 (220) ◽

pp. 283-293 ◽

Cited By ~ 20

Author(s):

Indrani Das ◽

Regine Hock ◽

Etienne Berthier ◽

Craig S. Lingle

Keyword(s):

Mass Loss ◽

Mass Balance ◽

High Elevation ◽

Center Line ◽

Laser Altimetry ◽

Tidewater Glaciers ◽

Airborne Laser ◽

Digital Elevation ◽

Stereo Imagery ◽

Elevation Model

AbstractAlaskan glaciers are among the largest regional contributors to sea-level rise in the latter half of the 20th century. Earlier studies have documented extensive and accelerated ice wastage in most regions of Alaska. Here we study five decades of mass loss on high-elevation, land-terminating glaciers of the Wrangell Mountains (~ 4900 km2) in central Alaska based on airborne center-line laser altimetry data from 2000 and 2007, a digital elevation model (DEM) from ASTER and SPOT5, and US Geological Survey topographic maps from 1957. The regional mass-balance estimates derived from center-line laser altimetry profiles using two regional extrapolation techniques agree well with that from DEM differencing. Repeat altimetry measurements reveal accelerated mass loss over the Wrangell Mountains, with the regional mass-balance rate evolving from –0.07 ± 0.19 m w.e. a–1 during 1957–2000 to –0.24 ± 0.16 m w.e. a–1 during 2000–07. Nabesna, the largest glacier in this region (˜1056 km2), lost mass four times faster during 2000–07 than during 1957–2000. Although accelerated, the mass change over this region is slower than in other glacierized regions of Alaska, particularly those with tidewater glaciers. Together, our laser altimetry and satellite DEM analyses demonstrate increased wastage of these glaciers during the last 50 years.

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Unraveling the retreat of the Aneto Glacier (Pyrenees, Spain) since the Little Ice Age

10.5194/egusphere-egu2020-1027 ◽

2020 ◽

Author(s):

Néstor Campos ◽

Jesús Alcalá ◽

C. Scott Watson ◽

Nelson Grima ◽

Ioannis Kougkoulos ◽

...

Keyword(s):

Ice Age ◽

Aerial Photographs ◽

Ice Thickness ◽

Massif Central ◽

Bedrock Topography ◽

Perfectly Plastic ◽

Digital Elevation ◽

Volumetric Reconstruction ◽

Longitudinal Profiles ◽

Elevation Model

The Aneto is the largest glacier of the Pyrenees, is located on the Maladeta Massif (Central Pyrenees), close to the highest point of the range, the Aneto peak (42&#176; 37' 52 N, 0&#176; 39' 24 E; 3,404 m a.s.l.). This glacier is 675 meters long, occupy an area of 48.64 ha and their maximum altitude is 3,269 meters. The glacier front ends at 3,029 m a.s.l. and its mean slope is 23.6&#176;, reaching a maximum of 56&#176; in some parts. The main aim of this research is to present a detailed volumetric reconstruction of the glacier since the LIA and analyze their retreat. Based on morphological features, the extent of the glacier has been reconstructed for different periods (LIA, 1957, 2000, 2006, 2015 and 2017) and their ice volume, maximum ice thickness and ELAs has been calculated. To delimitate the glacier extension during the LIA, the moraines have been mapped by using photo interpretation techniques. For the recent phases digital aerial photographs and satellite images have been used. To estimate the topography of the glacier we used a simple steady-state model that assumes a perfectly plastic ice rheology, reconstructing the theoretical ice profiles and obtaining the extent of the glaciers. Later, to reconstruct the ice surface we calculated longitudinal profiles, with these reconstructed profiles a digital elevation model was created and combined with the bedrock topography in order to obtain the ice thickness at each phase. This bedrock topography was obtained by combining the glacier topography with a 3D model of the glacier obtained with geo-radar (ERHIN program, Government of Aragon).This study reveals a great retreat of the Aneto Glacier since the LIA. The length of the glacier has been reduced from 1,970 m during the LIA to 675 m in 2017, and its tongue has retreated from 2,385 to 3,029 m a.s.l. during the same period. Regarding the area, it has been reduced from 245 ha during the LIA to 48.64 ha in 2017. During this period, the ELA has increased from 2,925 to 3,140 m a.s.l. The glacier volume has been reduced from 82.57 x106 m3 to 3.48 x106 m3, and the maximum ice thickness from 95 m to 27m. These data reveals a huge retreat of the glacier since the LIA, furthermore, this retreat has been more accelerated since the 50's.&#160;Research funded by PYRENEEND project (10.18258/11352)

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Geology mapping with an emphasis on the Quaternary in the Swiss Prealps and Molasse Plateau

10.5194/egusphere-egu2020-11161 ◽

2020 ◽

Author(s):

Valérie Baumann ◽

Marc-Henri Derron ◽

Jean-Luc Epard ◽

Michel Jaboyedoff

Keyword(s):

High Resolution ◽

Digital Elevation Model ◽

Genetic Material ◽

Ice Age ◽

Aerial Photographs ◽

Material Surface ◽

Terrain Classification ◽

Geological Maps ◽

Digital Elevation ◽

Elevation Model

The main goal of this project is to harmonise the different geological maps (scale 1:25.000) and to improve the Quaternary mapping of the region of &#8220;canton de Vaud&#8221; in Switzerland using a high resolution LiDAR digital elevation model, and geophysical or boreholes data. We present here the results for the geologic mapping of two test areas: one in the Prealps and the second in the Molasse Plateau.Detailed geological maps (scale 1:25.000) have been produced during the XX century for the whole region. During the last Late Glacial Maximum (LGM) the canton de Vaud area was covered by ice sheets, then soils and loose rock deposits were formed toward the end of ice age, however the Quaternary formations are sometimes not represented especially when their thickness is only of a few meters and the interpretation of geomorphologic features with aerial photographs was difficult in areas covered by forest. &#160;In recent years, the high-resolution digital elevation model derived from high resolution LiDAR data with the possibility to remove the trees in the forested areas offers the possibility to detect and interpret new morphologies.In this study, different LIDAR-derived hillshade maps have been used to improve the delimitation of bedrock and Quaternary formation through morphological feature analyse. Borehole data gave us fundamental data about geology and stratigraphy and field surveys were performed for selected places. Additionally, a terrain classification system first developed in Canada (Cruden and Thomson, 1987) was used to add information for each polygon like genetic material, surface expression, modifying processes and stratigraphic data. All the mapping was performed in a GIS (Geographic system information) environment.Detailed bedrock and Quaternary mapping will provide very good information for the management of the resources, land planning and geo-hazards. The additional information (terrain classification) for each polygon allow us to create different thematic maps starting from the geological map.&#160;Reference:&#160;Cruden, D. M., and S. Thomson.&#160;Exercises in terrain analysis. Pica Pica Press, 1987.&#160;

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Geomorphological information system: Physical model and options of geomorphological analysis

Geografie ◽

10.37040/geografie2006111010015 ◽

2006 ◽

Vol 111 (1) ◽

pp. 15-32

Author(s):

Pavel Mentlík ◽

Karel Jedlička ◽

Jozef Minár ◽

Ivan Barka

Keyword(s):

Information System ◽

Physical Model ◽

Digital Elevation Model ◽

Geomorphological Mapping ◽

Genetic Groups ◽

Digital Elevation ◽

Modelling Methodology ◽

Morphology And Morphometry ◽

Elevation Model ◽

Geomorphological Analysis

The paper has two main aims. Firstly, to postulate a physical geodatabase model of a geomorphological information system based on the already existing logical geodatabase model. Secondly, to define processes of geomorphological analysis based on the physical geodatabase model. The structure of the physical model follows the logical model and is divided into three parts: adopted layers (hydrology, geology, topography and others), basic layers (elementary forms, digital elevation model and derivatives, documentation materials, genetic groups of landforms, morphodynamic phenomena, basin based features and geomorphic network) and special layers (morphostructural analysis, comprehensive geomorphological analysis and so on). The geodatabase modelling methodology was used for developing the physical geodatabase model. The geomorphological analysis is based mainly on the layer of elementary forms (defined according to their morphology and morphometry) and the derived layer of morphogenetical forms (determined by genesis of landforms). The traditional methods of geomorphological mapping and also more recent concepts of geomorphological analysis were used. The concept is presented in the context of research in the surroundings of Prášilské jezero (lake) in the Šumava (Mts.). ESRI products were used to carry out the project.

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