23.3.2 Rock Glacier, Detection, Change, Flow

Chapter Contents (Back)
Glacier Motion. Rock Glacier.

Kenyi, L.W., Kaufmann, V.,
Estimation of rock glacier surface deformation using SAR interferometry data,
GeoRS(41), No. 6, June 2003, pp. 1512-1515.
IEEE Abstract. 0308
BibRef

Kaufmann, V.,
Detection And Quantification Of Rock Glacier Creep Using High-resolution Orthoimages Of Virtual Globes,
ISPRS12(XXXIX-B5:517-522).
DOI Link 1209
BibRef

Kaufmann, V.[Viktor], Ladstädter, R.[Richard],
Monitoring of Active Rock Glaciers by Means of Digital Photogrammetry,
PCV02(B: 108). 0305
BibRef

Gómez-Gutiérrez, Á.[Álvaro], de Sanjosé-Blasco, J.J.[José Juan], de Matías-Bejarano, J.[Javier], Berenguer-Sempere, F.[Fernando],
Comparing Two Photo-Reconstruction Methods to Produce High Density Point Clouds and DEMs in the Corral del Veleta Rock Glacier (Sierra Nevada, Spain),
RS(6), No. 6, 2014, pp. 5407-5427.
DOI Link 1407
BibRef

Gómez-Gutiérrez, Á.[Álvaro], de Sanjosé-Blasco, J.J.[José Juan], Lozano-Parra, J.[Javier], Berenguer-Sempere, F.[Fernando], de Matías-Bejarano, J.[Javier],
Does HDR Pre-Processing Improve the Accuracy of 3D Models Obtained by Means of two Conventional SfM-MVS Software Packages? The Case of the Corral del Veleta Rock Glacier,
RS(7), No. 8, 2015, pp. 10269.
DOI Link 1509
BibRef

Dall'Asta, E.[Elisa], Forlani, G.[Gianfranco], Roncella, R.[Riccardo], Santise, M.[Marina], Diotri, F.[Fabrizio], Morra di Cella, U.[Umberto],
Unmanned Aerial Systems and DSM matching for rock glacier monitoring,
PandRS(127), No. 1, 2017, pp. 102-114.
Elsevier DOI 1704
UAS BibRef

Villarroel, C.D.[Cristian Daniel], Beliveau, G.T.[Guillermo Tamburini], Forte, A.P.[Ana Paula], Monserrat, O.[Oriol], Morvillo, M.[Monica],
DInSAR for a Regional Inventory of Active Rock Glaciers in the Dry Andes Mountains of Argentina and Chile with Sentinel-1 Data,
RS(10), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef

Bodin, X.[Xavier], Thibert, E.[Emmanuel], Sanchez, O.[Olivier], Rabatel, A.[Antoine], Jaillet, S.[Stéphane],
Multi-Annual Kinematics of an Active Rock Glacier Quantified from Very High-Resolution DEMs: An Application-Case in the French Alps,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Bertone, A.[Aldo], Zucca, F.[Francesco], Marin, C.[Carlo], Notarnicola, C.[Claudia], Cuozzo, G.[Giovanni], Krainer, K.[Karl], Mair, V.[Volkmar], Riccardi, P.[Paolo], Callegari, M.[Mattia], Seppi, R.[Roberto],
An Unsupervised Method to Detect Rock Glacier Activity by Using Sentinel-1 SAR Interferometric Coherence: A Regional-Scale Study in the Eastern European Alps,
RS(11), No. 14, 2019, pp. xx-yy.
DOI Link 1908
BibRef

Strozzi, T.[Tazio], Caduff, R.[Rafael], Jones, N.[Nina], Barboux, C.[Chloé], Delaloye, R.[Reynald], Bodin, X.[Xavier], Kääb, A.[Andreas], Mätzler, E.[Eva], Schrott, L.[Lothar],
Monitoring Rock Glacier Kinematics with Satellite Synthetic Aperture Radar,
RS(12), No. 3, 2020, pp. xx-yy.
DOI Link 2002
BibRef

Winiwarter, L.[Lukas], Anders, K.[Katharina], Höfle, B.[Bernhard],
M3C2-EP: Pushing the limits of 3D topographic point cloud change detection by error propagation,
PandRS(178), 2021, pp. 240-258.
Elsevier DOI 2108
Level of Detection, Wald-Test, Signal-Noise-Separation, Terrestrial Laser Scanning, Rock Glacier, Geomorphic Monitoring BibRef

Zhang, X.F.[Xue-Fei], Feng, M.[Min], Zhang, H.[Hong], Wang, C.[Chao], Tang, Y.X.[Yi-Xian], Xu, J.H.[Jin-Hao], Yan, D.Z.[De-Zhao], Wang, C.L.[Chun-Ling],
Detecting Rock Glacier Displacement in the Central Himalayas Using Multi-Temporal InSAR,
RS(13), No. 23, 2021, pp. xx-yy.
DOI Link 2112
BibRef

Cai, J.X.[Jia-Xin], Wang, X.W.[Xiao-Wen], Liu, G.X.[Guo-Xiang], Yu, B.[Bing],
A Comparative Study of Active Rock Glaciers Mapped from Geomorphic- and Kinematic-Based Approaches in Daxue Shan, Southeast Tibetan Plateau,
RS(13), No. 23, 2021, pp. xx-yy.
DOI Link 2112
BibRef

Zahs, V.[Vivien], Winiwarter, L.[Lukas], Anders, K.[Katharina], Williams, J.G.[Jack G.], Rutzinger, M.[Martin], Höfle, B.[Bernhard],
Correspondence-driven plane-based M3C2 for lower uncertainty in 3D topographic change quantification,
PandRS(183), 2022, pp. 541-559.
Elsevier DOI 2201
Change detection, Terrestrial laser scanning, Point clouds, Level of detection, Rock glacier BibRef

Bearzot, F.[Francesca], Garzonio, R.[Roberto], Colombo, R.[Roberto], Crosta, G.B.[Giovanni Battista], di Mauro, B.[Biagio], Fioletti, M.[Matteo], Morra di Cella, U.[Umberto], Rossini, M.[Micol],
Flow Velocity Variations and Surface Change of the Destabilised Plator Rock Glacier (Central Italian Alps) from Aerial Surveys,
RS(14), No. 3, 2022, pp. xx-yy.
DOI Link 2202
BibRef

Williams, J.M.[Joshua M.], Scuderi, L.A.[Louis A.], Newsom, H.E.[Horton E.],
Numerical Analysis of Putative Rock Glaciers on Mount Sharp, Gale Crater, Mars,
RS(14), No. 8, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Martínez-Fernández, A.[Adrián], Serrano, E.[Enrique], Pisabarro, A.[Alfonso], Sánchez-Fernández, M.[Manuel], de Sanjosé, J.J.[José Juan], Gómez-Lende, M.[Manuel], Rangel-de Lázaro, G.[Gizéh], Benito-Calvo, A.[Alfonso],
The Influence of Image Properties on High-Detail SfM Photogrammetric Surveys of Complex Geometric Landforms: The Application of a Consumer-Grade UAV Camera in a Rock Glacier Survey,
RS(14), No. 15, 2022, pp. xx-yy.
DOI Link 2208
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Kaldybayev, A.[Azamat], Sydyk, N.[Nurmakhambet], Yelisseyeva, A.[Alena], Merekeyev, A.[Aibek], Nurakynov, S.[Serik], Zulpykharov, K.[Kanat], Issanova, G.[Gulnura], Chen, Y.N.[Ya-Ning],
The First Inventory of Rock Glaciers in the Zhetysu Alatau: The Aksu and Lepsy River Basins,
RS(15), No. 1, 2023, pp. xx-yy.
DOI Link 2301
BibRef

Fleischer, F.[Fabian], Haas, F.[Florian], Altmann, M.[Moritz], Rom, J.[Jakob], Ressl, C.[Camillo], Becht, M.[Michael],
Glaciogenic Periglacial Landform in the Making: Geomorphological Evolution of a Rockfall on a Small Glacier in the Horlachtal, Stubai Alps, Austria,
RS(15), No. 6, 2023, pp. 1472.
DOI Link 2304
BibRef

Buchelt, S.[Sebastian], Blöthe, J.H.[Jan Henrik], Kuenzer, C.[Claudia], Schmitt, A.[Andreas], Ullmann, T.[Tobias], Philipp, M.[Marius], Kneisel, C.[Christof],
Deciphering Small-Scale Seasonal Surface Dynamics of Rock Glaciers in the Central European Alps Using DInSAR Time Series,
RS(15), No. 12, 2023, pp. xx-yy.
DOI Link 2307
BibRef

Prates, G.[Gonçalo], Vieira, G.[Gonçalo],
Surface Displacement of Hurd Rock Glacier from 1956 to 2019 from Historical Aerial Frames and Satellite Imagery (Livingston Island, Antarctic Peninsula),
RS(15), No. 14, 2023, pp. 3685.
DOI Link 2307
BibRef

Martínez-Fernández, A.[Adrián], Serrano, E.[Enrique], de Sanjosé-Blasco, J.J.[José Juan], Gómez-Lende, M.[Manuel], Sánchez-Fernández, M.[Manuel], Pisabarro, A.[Alfonso], Atkinson, A.[Alan],
Multiple Close-Range Geomatic Techniques for the Kinematic Study of the La Pael Rock Glacier, Southern Pyrenees,
RS(16), No. 1, 2024, pp. xx-yy.
DOI Link 2401
BibRef

Ma, Q.Q.[Qi-Qi], Oguchi, T.[Takashi],
Rock Glacier Inventory of the Southwestern Pamirs Supported by InSAR Kinematics,
RS(16), No. 7, 2024, pp. 1185.
DOI Link 2404
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Boesch, R., Graf, C.,
Mass Movements of An Alpine Rock Glacier,
UAV-g19(215-219).
DOI Link 1912
BibRef

Martínez-Fernández, A., Serrano, E., Sanjosé, J.J., Gómez-Lende, M., Pisabarro, A., Sánchez, M.,
Geomatic Methods Applied to The Change Study of The La Paúl Rock Glacier, Spanish Pyrenees,
CHGCS19(1771-1775).
DOI Link 1912
BibRef

Dall'Asta, E., Delaloye, R., Diotri, F., Forlani, G., Fornari, M., di Cella, U.M.[U. Morra], Pogliotti, P., Roncella, R., Santise, M.,
Use of UAS in a High Mountain Landscape: The Case of Gran Sommetta Rock Glacier (AO),
GeoUAV15(391-397).
DOI Link 1602
BibRef

de Matías, J., Moreno, J., de Sanjosé, J.J., Guerrero, J.J.,
Image Measurement Techniques In Rock Glacier Modelling,
CloseRange10(xx-yy).
PDF File. 1006
BibRef

Chapter on Remote Sensing General Issue, Land Use, Land Cover continues in
Snow Cover, Snow Depth, Snow Analysis .


Last update:Nov 26, 2024 at 16:40:19