The Rogowiec Landslide Complex (Central Sudetes, SW Poland) : a case of a collapsed mountain

Kasprzak, M.; Duszyński, F.; Jancewicz, K.; Michniewicz, A.; Różycka, M.; Migoń, P.

doi:10.7306/gq.1286

Artykuł - szczegóły

Tytuł artykułu

The Rogowiec Landslide Complex (Central Sudetes, SW Poland) : a case of a collapsed mountain

Autorzy

Kasprzak M. , Duszyński F. , Jancewicz K. , Michniewicz A. , Różycka M. , Migoń P.

Treść / Zawartość

Pełne teksty:

Kasprzak_M_The Rogowiec_Geol. Quart._Vol. 60_No 3_2016.pdf

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Identyfikatory

DOI

10.7306/gq.1286

Warianty tytułu

Języki publikacji

Abstrakty

The paper focuses on a large relict landslide complex in the northeastern part of the Kamienne Mts. (Sudetes, SW Poland) developed on Carboniferous and Permian volcanic and clastic sedimentary rocks. Whilst the presence of mass movements around Mt. Rogowiec has long been known, no attempts have yet been made to offer a comprehensive analysis. This study is based on recognition of geomorphic features from LiDAR-derived DTM, geomorphometric analysis, field geomorphological mapping, joint measurements at representative exposures, and electrical resistivity tomography. The total area affected by gravitational slope deformation exceeds 40 ha and consists of a few smaller units that show distinctive patterns of displacement. The eastern slopes of the Mt. Rogowiec ridge have been reshaped by large slides involving rigid blocks of trachyandesite in the upper part and deformed sedimentary successions in the middle and lower part. The central part of the area has experienced lateral spreading which resulted in complete disintegration of the volcanic cap. Fresh-looking ridge-top trenches indicate that this process is ongoing. Subsequent movements included flows into pre-existing valleys and rock wall collapses to produce spectacular block streams. The scale and variety of deformation structures at Mt. Rogowiec make this locality unique in the Sudetes.

Słowa kluczowe

landslide hillslopes digital terrain model (DTM) LiDAR geomorphometry electrical resistivity tomography

Wydawca

Państwowy Instytut Geologiczny - Państwowy Instytut Badawczy

Czasopismo

Geological Quarterly

Rocznik

2016

Tom

Vol. 60, No. 3

Strony

695--713

Opis fizyczny

Bibliogr. 63 poz., rys., tab., wykr.

Twórcy

autor

Kasprzak M.

University of Wrocław, Institute of Geography and Regional Development, pl. Uniwersytecki 1, 50-137 Wrocław, Poland

autor

Duszyński F.

University of Wrocław, Institute of Geography and Regional Development, pl. Uniwersytecki 1, 50-137 Wrocław, Poland

autor

Jancewicz K.

University of Wrocław, Institute of Geography and Regional Development, pl. Uniwersytecki 1, 50-137 Wrocław, Poland

autor

Michniewicz A.

University of Wrocław, Institute of Geography and Regional Development, pl. Uniwersytecki 1, 50-137 Wrocław, Poland

autor

Różycka M.

University of Wrocław, Institute of Geography and Regional Development, pl. Uniwersytecki 1, 50-137 Wrocław, Poland

autor

Migoń P.

piotr.migon@uwr.edu.pl

University of Wrocław, Institute of Geography and Regional Development, pl. Uniwersytecki 1, 50-137 Wrocław, Poland

Bibliografia

1. Aichler, J., Pecina, V., 1998. Documentation of landslides connected with the floods in 1977 in the Jeseníky area (in Czech with English summary). Geologické výzkumy na Moravě a ve Slezsku w roce 1997: 94-96. Český geologický Ústav, Brno, .
2. Agliardi, F., Crosta, G., Zanchi, A., 2001. Structural constraints on deep-seated slope deformation kinematics. Engineering Geology, 59: 83-102.
3. Allmendinger, R.W., 2013. Stereonet Help - the user's manual for Stereonet 8.
4. Allmendinger, R.W., Cardozo, N.C., Fisher, D., 2012. Structural Geology Algorithms: Vectors and Tensors. Cambridge University Press, Cambridge.
5. Awdankiewicz, M., 1999. Volcanism in a late Variscan intramontane trough: Carboniferous and Permian volcanic centers of the Intra-Sudetic Basin, SW Po land. Geologia Sudetica, 32: 13-47.
6. Ballantyne, C.K., Wilson, P., Schnabel, C., Xu, S., 2013. Late glacial rock slope failures in north-west Ire land: age, causes and implications. Journal of Quaternary Sciences, 28: 789-802.
7. Boguszewicz, A., 2010. Corona Silesiae. Zamki Piastów furstenberskich na południowym pograniczu księstwa jaworskiego, świdnickiego i ziębickiego do połowy XIV wieku (in Polish). Wydział Nauk Historycznych i Pedagogicznych Uniwersytetu Wrocławskiego, Katedra Etnologii i Antropologii Kulturowej. Wrocław.
8. Boguszewicz, A., Dwojak, A., Ziółkowski, W., 1991. Zamek Rogowiec. Wyniki prac archeologiczno-architektonicznych w 1989 r. (in Polish). Śląskie Sprawozdania Archeologiczne, 32: 263-299.
9. Bossowski, A., Ihnatowicz, A., 1994. Palaeogeography of the uppermost Carboniferous and lowermost Permian deposits in NE part of the Intra-Sudetic Depression. Geological Quarterly, 38 (4): 709-726.
10. Bossowski, A., Cymerman, Z., Grocholski, A., Ihnatowicz, A., 1994. Szczegółowa Mapa Geologiczna Sudetów 1:25 000, arkusz Jedlina Zdrój (in Polish). Wyd. Geol., Warszawa.
11. Brunsden, D., Jones, D.K.C, 1976. The evolution of landslide slopes in Dorset. Philosophical Transactions of the Royal Society of London, A283: 605-631.
12. Busche, D., 1980. On the ori gin of the Msak Mallat and Hamadat Manghini Escarpment. In: The Geology of Libya (eds. M.J. Salem and M.T. Busrewil): 837-848. Academic Press, London.
13. Cardozo, N., Allmendinger, R.W., 2013. Spherical projections with OSXStereonet. Computers & Geosciences, 51: 193-205.
14. Carpentier, S., Konz, M., Fischer, R., Anagnostopoulos, G., Meusburger, K., Schoeck, K., 2012. Geophysical imaging of shallow subsurface topography and its implication for shallow landslide susceptibility in the Urseren Valley, Switzerland. Journal of Applied Geophys i cs, 83: 46-56.
15. Conti, S., Tosatti, G., 1996. Tectonic vs gravitational processes affecting Ligurian and Epiligurian units in the Marecchia valley (northern Apennines). Memorie di Scienze Geologiche, 48: 107-142.
16. Crozier, M.J., 2010. Landslide geomorphology: An argument for recognition, with examples from New Zealand. Geomorphology, 90: 3-15.
17. Cruden, D.M., Varnes, D.J., 1996. Landslide types and processes. In: Landslides: Investigation and Mitigation (eds. A.K. Turner and R.L. Schuster), 247: 36-75. Transportation Research Board, National Academy of Sciences, Washi ngton D.C., Special Report.
18. Czerwiński, J., Żurawek, R., 1999. The geomorphological effects of heavy rainfalls and flooding in the Polish Sudetes in July 1997. Studia Geomorphologica Carpatho-Balcanica, 33: 27-43.
19. Dathe, E., Berg, G. 1926. Erläuterungen zur Geologischen Karte von Preußen und benachbarten deutschen Ländern. Lieferung 145. Blatt Waldenburg i. Schl. Berlin (2. Aufl.).
20. Dathe, E., Zimmermann, E., Berg, G., 1910. Erläuterungen zur Geologischen Karte von Preußen und benachbarten Bundesstaaten. Lieferung 145. Blatt Friedland i. Schl. Berlin.
21. Fisher, N.I., 1995. Statistical Analysis of Circular Data. Cambridge University Press, Cambridge.
22. Forczek, I., 2008. Destruction of marginal parts of sandstone plateaus in the Protected Landscape Area Bohemian Paradise. Acta Geodynamica et Geomaterialia, 5: 267-274.
23. Grocholski, A., 1972. Ślady osuwisk na stokach Lesistej Wielkiej w Górach Kamiennych (in Polish). Polskie Towarzystwo Miłośników Nauk o Ziemi, Koło Górnicze w Gorcach, Biuletyn Informacyjny, 11: 9-14.
24. Gutiérrez, F., Linares, R., Roqué, C., Zarroca, M., Rosell, J., Galve, J.P., Carbonell, D., 2012. Investigating gravitational grabens related to lateral spreading and evaporite dissolution subsidente by means of detailed mapping, trenching, and electrical resistivity tomography (Spanish Pyrenees). Lithosphere, 4: 331-353.
25. Hutchinson, J.N., 1995. Deep-seated mass movements on slopes. Memorie della Societa Geologica Italiana, 50: 147-164.
26. Jahn, A., 1964. Slopes morphological features resulting from gravitation. Zeitschrift für Geomorphologie, Suppl.-Bd., 5: 59-72.
27. Jarman, D., 2006. Large rock slope failures in the Highl ands of Scotland: characterisation, causes and spatial distribution. Engineering Geology, 83: 161-182.
28. Kacprzak, A., Migoń, P., Musielok, Ł., 2013. Using soils as indicators of past slope instability in forested terrain, Kamienne Mts, SW Poland. Geomorphology, 194: 65-75.
29. Kneisel, C., 2006. Assessment of subsurface lithology in mountain environments using 2D resistivity imaging. Geomorphology, 80: 32-44.
30. Loke, M.H., 2000. Electrical imaging syrveys for environmental and engineering studies. A practical guide to 2-D and 3-D surveys, Geotomo. Malaysia.
31. Loke, M.H., Chambers, J.E., Rucker, D.F., Kuras, O., Wilkinson, P.B., 2013. Recent developments in the direct-current geoelectrical imaging method. Journal of Applied Geophysics, 95: 135-156.
32. Migoń, P., Kasprzak, M., 2011. Morfologiczny zapis ruchów masowych na progach morfologicznych Gór Stołowych w świetle numerycznego modelu wysokości o dużej rozdzielczości (in Polish). Przyroda Sudetów, 14: 115-124.
33. Migoń, P., Kasprzak, M., 2015. LiDAR DEM-based analysis of geomorphology of the Szczeliniec Wielki mesa in Poland's Stołowe Mountains (in Polish with English summary). Przegląd Geograficzny, 87: 27-52.
34. Migoń, P., Kasprzak, M., 2016. Pathways of geomorphic evolution of sandstone escarpments in the Góry Stołowe table land (SW Poland) - insights from LiDAR-based high-resolution DEM. Geomorphology, 260: 51-63.
35. Migoń, P., Placek, A., 2014. Lithological and structural control on the relief of the Sudetes (in Polish with English summary). Przegląd Geologiczny, 62: 36-43.
36. Migoń, P., Pánek, T., Malik, I., Hrádecký, J., Owczarek, P., Šilhán, K., 2010. Complex landslide terrain in the Kamienne Mountains, Middle Sudetes, SW Poland. Geomorphology, 124: 200-214.
37. Migoń, P., Kacprzak, A., Malik, I., Kasprzak, M., Owczarek, P., Wistuba, M., Pánek, T., 2014a. Geomorphological, pedological and dendrochronological signatures of a relict landslide terrain, Mt Garbatka (Kamienne Mts), SW Poland. Geomorphology, 219: 213-231.
38. Migoń, P., Jancewicz, K., Kasprzak, M., 2014b. The extent of landslide-affected areas in the Kamienne Mountains (Middle Sudetes) - a comparison of geological maps and a LiDAR based digital elevation model (in Polish with English summary). Przegląd Geologiczny, 62: 463-471.
39. Migoń, P., Różycka, M., Michniewicz, A., Kasprzak, M., 2015. Identyfikacja form osuwiskowych na podstawie danych LiDAR - wybrane przykłady z Sudetów Środkowych i Zachodnich (in Polish). In: Ogólnopolska Konferencja Osuwisko, 19-22 maja 2015, Wieliczka: 107-108. Państwowy Instytut Geologiczny - Państwowy Instytut Badawczy, Warszawa.
40. Migoń, P., Duszyński, F., Jancewicz, K., Różycka, M., Kasprzak, M., 2016. Large-scale slope remodelling by landslides - geomorphic diversity and geological controls, Kamienne Mts, Central Europe. Geomorphology, DOI: 10.1016/j.geomorph.2016.09.037
41. Olaya, V., Conrad, O., 2008. Geomorphometry in SAGA. In: Geomorphometry: Concepts, Software, Applications. Developments in Soil Science (eds. T. Hengl and H.I. Reuter), 33: 293-308. Elsevier.
42. Pánek, T., Hradecký, J., Šilhán, K., 2008. Application of electrical resistivity to mography (ERT) in the study of various types of slope deformations in anisotropic bedrock: case studies from the Flysch Carpathians. Studia Geomorphologica Carpatho-Balcanica, 42: 57-73.
43. Pánek, T., Tábořík, P., Klimeš, J., Komárková, V., Hradecký, J., Š astný, M., 2011. Deep-seated gravitational slope deformations in the highest parts of the Czech Flysch Carpathians: evolutionary model based on kinematic analysis, electrical imaging and trenching. Geomorphology, 129: 92-112.
44. Pašek, J., Demek, J., 1969. Mass movements near the community of Stadice in north western Bohemia. Studia Geographica (Brno), 3: 1-17.
45. Pašek, J., Pulinowa, M.Z., 1976. Block movements of Cretaceous sandstones in the Stolowe Gory Mts., Poland. Bulletin of the International Association of Engineering Geology, 13: 79-82.
46. Pasuto, A., Soldati, M., 1996. Rock spreadl ng. In: Landslide Recognition (eds. R. Dikau, D. Brunsden, L. Schrott and M.-L. Ibsen): 122-136. Wiley, Chichester.
47. Perrone, A., Lapenna, V., Piscitelli, S., 2014. Electrical resistivity tomography technique for landslide investigation: a review. Earth-Science Reviews, 135: 65-82.
48. Pilous, V., 1977. Strukturní mury v Krkonoších - III. část. Opera Corcontica, 14: 7-94.
49. Placek, A., 2011. Rzeźba strukturalna Sudetów w świetle wyników pomiarów wytrzymałości skał i analiz numerycznego modelu wysokości (in Polish). Rozprawy Naukowe Instytutu Geografii i Rozwoju Regionalnego Uniwersytetu Wrocławskiego, 16: 1-190.
50. Pulinowa, M.Z., 1972. Landslide processes in man-made and natural environment. Dokumentacja Geograficzna IG PAN, 4.
51. Reynolds, J.M., 2011. An Introduction to Applied and Environmental Geophysics (2nd Edition). Wiley, Chichester.
52. Różycka, M., Michniewicz, A., Migoń, P., Kasprzak, M., 2015. Identification and morphometric properties of landslides in the Bystrzyckie Mountains (Sudetes, SW Po l and) based on data derived from airborne LiDAR. In: Geomorphometry for Geosciences (eds. J. Jasiewicz, Z. Zwoliński, H. Mitasova and T. Hengl): 247-250. Adam Mickiewicz University in Poznań - Institute of Geoecology and Geoinformation, International Society for Geomorphometry, Poznań.
53. Rybář, J., 2002. Regional types of deep-seated slope failures in the areas of Tertiary volcanics in the Bohemian Massif. In: Landslides (eds. J. Rybář, J. Stemberk and G. Wagner): 299-303. Swets & Zeitlinger, Lisse.
54. Samouelian, A., Cousin, I., Tabbagh, A., Bruand, A., Richard, G., 2005. Electrical resistivity survey in soil science: a review. Soil and Tillage Research, 83: 173-193.
55. Schrott, L., Sass, O., 2008. Application of field geophysics in geomorphology: Advances and limitations exemplified by case studies. Geomorphology, 93: 55-73.
56. Sithole, G., Vosselman, G., 2004. Experimental comparison of filter algorithms for bare-Earth extraction from airborne laser scanning point clouds. ISPRS Journal of Photogrammetry and Remote Sensing, 59: 85-101.
57. Sorensen, R., Zinko, U., Seibert, J., 2006. On the calculation of the topographic wetness index: evaluation of different methods based on field observations. Hydrology and Earth System Sciences, 10: 101-112.
58. Synowiec, G., 2003. Landslides in the Kamienne Mts, Sudetes (SW Poland) (in Polish with English summary). Przegląd Geologiczny, 51: 59-65.
59. Synowiec, G., 2005. Formy i procesy osuwiskowe w Górach Kamiennych (in Polish). Unpublished PhD thesis, Instytut Geografii i Rozwoju Regionalnego, Uniwersytet Wrocławski.
60. Vlcko, J., 2004. Extremely slow slope movements influencing the stability of Spis Castle, UNESCO site. Landslides, 1: 67-71.
61. Wężyk, P., ed., 2014. Podręcznik dla uczestników szkoleń z wykorzystania produktów LiDAR (in Polish). Informatyczny System Osłony Kraju przed nadzwyczajnymi zagrożeniami, Główny Urząd Geodezji i Kartografii, Warszawa.
62. Zaruba, Q., Mencl, V., 1982. Landslides and Their Control. Elsevier, Amsterdam.
63. Żurawek, R., 1999. Zmiany erozyjne w dolinach rzek Sudetów Kłodzkich wywołane powodziami w lipcu 1997 r. oraz w lipcu 1998 r. (in Polish). Problemy Zagospodarowania Ziem Górskich, 45: 43-61.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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