Application of Electrical Resistivity Tomography (ERT)in the investigation of quaternary landslide zones, based on the selected regions of Płock slope

• Autorzy: Kaczmarek Ł. , Mieszkowski R. , Kołpaczyński M , Pacanowski G.

Identyfikatory

DOI

10.2478/squa-2014-0010

• Języki publikacji: EN

Abstrakty

EN

The article shows the results of geophysical surveys performed by using Electrical Resistivity Tomography (ERT) method on selected ragion of Płock slope of a Tumski hill near Basilica of Assumption of the Blessed Virgin Mary in Płock and in Maszewo by the Vistula River a few kilometers north of Płock. The above-mentioned sections were selected due to landslide phenomena observed there. Geophysical surveys were conducted in order to verify the state of the distribution of electrical resistivity in the sectors where mass movement was identified. The electrofusion crosssection near Cathedral Basilica shows clays and sands. Also in ERT prospection a zone of loose soils with high resistance is clearly visible. The results of the ERT method from Maszewo, indicates historical land surface of a landslide and that the slope in Maszewo consists of cohesive deposits. In order to describe these particular issues, geological cross-sections and safety factor obtained by calculation are presented for the analyzed parts of the slope. The safety factor shows that probability of landslide activity near Cathedral Basilica is very unlikely and in Maszewo is very high.

Słowa kluczowe

EN

slope stability; Płock slope; electrical resistivity tomography ERT; Quaternary

• Wydawca: Institute of Geological Science Polish Academy of Science
• Czasopismo: Studia Quaternaria
• Rocznik: 2014
• Tom: Vol. 31, Nr 2
• Strony: 101--107
• Opis fizyczny: Bibliogr. 27 poz., rys.

Twórcy

autor

Kaczmarek Ł.

• University of Warsaw, Faculty of Geology, Institute of Hydrogeology and Engineering Geology, Żwirki i Wigury 93, 02-089 Warsaw

autor

Mieszkowski R.

• University of Warsaw, Faculty of Geology, Institute of Hydrogeology and Engineering Geology, Żwirki i Wigury 93, 02-089 Warsaw

autor

Kołpaczyński M

• Geotechnika Mazowsze s.c., Żwirki i Wigury 93, room 3030 (building of the Faculty of Geology of the University of Warsaw), 02-089 Warsaw

autor

Pacanowski G.

• Polish Geological Institute – Polish Research Institute, Rakowiecka 4, 00-975 Warsaw

Bibliografia

• 1. Bestyński Z., Trojan J. 1975. Metody geofizyczne w badaniu statecznoœci zboczy skalnych. Badanie i prognozowanie osuwisk na zboczach zbiorników wodnych we fliszu karpackim. Konferencja PK MK WZ, IMGW, 155–170.
• 2. Bichler, A., Bobrowsky, P., Best, M., Douma, M., Hunter, J., Calvert, T., Burns, R. 2004. Three-dimensional mapping of a landslide using a multigeophysical approach: the Quesnel Forks landslide. Landslides 1, 29–40.
• 3. Bogoslovsky, V.A., Ogilvy, A.A. 1977. Geophysical methods for the investigation of landslides. Geophysics 42, 562–571.
• 4. Friedel, S., Thielen, A., Springman, S.M. 2006. Investigation of a slope endangered by rainfall-induced landslides using 3D resistivity tomography and geotechnical testing. Journal of Applied Geophysics 100, 100–114.
• 5. Gaudio, A., Bottino, G. 2001. Electrical and electromagnetic investigation for landslide characterization. Physics and Chemistry of the Earth. Part C: Solar- Terrestial and Planetary Science 26, 705–710.
• 6. Göktürkler, G., Balk Aya, Ç., Erhan, Z. 2008. Geophysical investigation of a landslide: The Altnda landslide Site, zmir (western Turkey). Journal of Applied Geophysics 65 (2), 84–96.
• 7. Grabowski D. 2010. Mapa osuwisk i terenów zagrożonych ruchami masowymi ziemi, skala 1:10000, powiat Płocki, Wyd. PIG, Warszawa.
• 8. Hack, R.. 2000. Geophysics for slope stability. Surveys in Geophysics 21, 423–448.
• 9. Keller G.V. and Frischknecht F.C.1966. Electrical methods in geophysical prospecting. Pergamon Press Inc., Oxford.
• 10. Kirsch R., (ed.) 2009. Groundwater Geophysics, A Tool for Hydro- geology, 2ed ed., Springer. New York
• 11. Lapenna, V., Lorenzo, P., Perrone, A., Piscitelli, S., Rizzo, E., Sdao, F. 2005. 2D electrical resistivity imaging of some complex landslides in Lucanian Apennine chain, southern Italy. Geophysics 70, B11–B18.
• 12. Le Roux, O., Jongmans, D., Kasperski, J., Schwartz, S. and Potherat, P. 2011. Deep geophysical investigation of the large Séchilienne landslide (Western Alps, France) and calibration with geological data. Engineering Geology 120 (1–4), 18–31.
• 13. Loke M.H., Barker R.D. 1996. Rapid least squares inversion of apparent resistivity pseudosections by a quasi-Newton method. Geophysical Prospecting 44, 131–152.
• 14. Loke M. H. 2012. Tutorial: 2-D and 3-D electrical imagining surveys. Geotomo Software, Malaysia.
• 15. Marescot L., Monnet R., Chapellier D. 2008. Resistivity and induced polarization surveys for slope instability studies in the Swiss Alps. Engineering Geology 98 18–28.
• 16. Mauritsch, H.J., Seiberl, W., Arndt, R., Römer, A., Schneiderbauer, K., Sendlhofer, G.P. 2000. Geophysical investigations of large landslides in the Carnic Region of southern Austria. Engineering Geology 56 373–388.
• 17. McCann, D.M., Forster, A. 1990. Reconnaissance geophysical methods in landslide investigations. Engineering Geology 29, 59–78.
• 18. Ostrowski, S., Pacanowski, G. 2011. Near surface geophysical prospecting using engineer seismic and electric resistivity tomography. Bulletins of the Polish Geological Institute 446, 215–224.
• 19. Ostrowski S., Rybak-Ostrowska B., Lasocki M. 2013. Wykorzystanie przypowierzchniowych badań geofizycznych w rozpoznaniu budowy geologicznej na przykładzie stref osuwiskowych w Karpatach. Przegl¹d Geologiczny Tom 61 Nr 1 r. 2013, 67–73.
• 20. Perrone, A., Iannuzzia, A., Lapenna, V., Lorenzo, P., Piscitelli, S., Rizzo, E., Sdao, F. 2004. High-resolution electrical imaging of the Varco d’Izzo earthflow (southern Italy). Journal of Applied Geophysics 56, 17–29.
• 21. Skompski S., Słowański W., 1962. Szczegółowa Mapa Geologiczna Polski 1:50000. PIG, Warszawa.
• 22. Socco, L. V., Jongmans, D., Boiero, D., Stocco, S., Maraschini, M., Tokeshi, K., Hantz, D. 2010. Geophysical investigation of the Sandalp rock avalanche deposits. Journal of Applied Geophysics Volume 70, 277–291.
• 23. Stenzel, P., Szymanko, J. 1973. Metody geofizyczne w badaniach hydrogeologicznych i geologiczno inżynierskich. Wyd. Geologiczne, Warszawa.
• 24. Tetegan, M., Pasquier, C., Besson, A., Nicoullaud, B., Bouthier, A., Bourennane, H., Desbourdes, C., King, D., Cousin, I. 2012. Field-scale estimation of the volume percentage of rock fragments in stony soils by electrical resistivity. Catena Volume: 92, 67–74.
• 25. Wysokiński L. (ed.) 1991. Posadowienie obiektów budowlanych w sąsiedztwie skarp i zboczy. Instrukcja nr 304. Instytut Techniki Budowlanej. Warszawa.
• 26. Wysokiński L. (ed.) 1998. Konferencja Naukowo-Techniczna: Przemieszczenia Skarpy Płockiej, ITB, Płock, 107–151.
• 27. Wysokiński L. (ed.) 2011. Ocena stateczności skarp i zboczy. Zasady wyboru zabezpieczeń. Instrukcja. Instrukcja nr 424. Instytut Techniki Budowlanej. Warszawa.