Top

Rock Mechanics and Rock Engineering

Published in:

24-10-2019 | Original Paper

Geomechanical Field Survey to Identify an Unstable Rock Slope: The Passo della Morte Case History (NE Italy)

Authors: Alberto Bolla, Paolo Paronuzzi

Published in: Rock Mechanics and Rock Engineering | Issue 4/2020

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

In this work, a geomechanical study performed on a natural rock slope located in north-eastern Italy (Tagliamento River valley, Friuli Venezia Giulia Region) is presented. The detailed geomechanical survey has provided a large bulk of field data proving that the investigated limestone slope is characterized by strong rock mass damage, thus resulting in a critical stability condition. Field evidence includes: (1) local faults crossing the rock mass and representing internal sliding surfaces; (2) slickensides and fault slips within the rock mass; (3) fracture joints of gravity-induced origin; (4) strong rock mass damage in over-stressed zones of the slope; and (5) slope monitoring data recorded by some installed devices. Three failure scenarios have been identified: a wedge failure involving a limestone block of 110,000 m³ (failure scenario 1: BLOCK1); a larger wedge failure involving an assembled limestone block of 200,000 m³ (failure scenario 2: BLOCK1-2-3); and a retrogressive failure involving a rear dolomitic block possibly triggered by the collapse of the limestone slope, mobilizing a maximum volume of 335,000 m³ (failure scenario 3: DOLOMITIC BLOCK). This paper shows that to comprehensively study stability problems involving natural rock slopes we must consider the interaction between pre-existing discontinuities, internal sub-blocks subdividing the unstable slope, rock mass strength and gravity-induced fractures that form during the delicate phase preceding slope collapse. Gravity-induced joints can be differentiated on the field from those of tectonic origin on the basis of some geometrical features, in particular their lower persistence and higher joint roughness.

next article A Novel Method for Predicting Movement and Damage of Overburden Caused by Shallow Coal Mining

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Abele G (1974) Bergstürze in den Alpen: ihre Verbreitung, Morphologie und Folgeerscheinungen. Wissenschlaftliche Alpenvereinshefte 25, München

Abele G (1994) Large rockslides: their causes and movement on internal sliding planes. Mt Res Dev 14:315–320CrossRef

Agliardi F, Crosta GB, Meloni F, Valle C, Rivolta C (2013) Structurally-controlled instability, damage and slope failure in a porphyry rock mass. Tectonophysics 605:34–47CrossRef

Aydin A, Basu A (2005) The Schmidt hammer in rock material characterization. Eng Geol 81:1–14CrossRef

Barla G, Antolini F, Barla M, Mensi E, Piovano G (2010) Monitoring of the Beauregard landslide (Aosta Valley, Italy) using advanced and conventional techniques. Eng Geol 116:218–235CrossRef

Barton N, Bandis S (1990) Review of predictive capabilities of JRC-JCS model in engineering practice. In: Barton N, Stephansson O (eds) Proceeding of the international symposium on rock joints. Balkema, Rotterdam, pp 603–610

Barton N, Choubey V (1977) The shear strength of rock joints in theory and practice. Rock Mech 10:1–54CrossRef

Basu A, Aydin A (2004) A method for normalization of Schmidt hammer rebound values. Int J Rock Mech Min Sci 41:1211–1214CrossRef

Bolla A, Paronuzzi P (2017) Stress-strain modeling to investigate the internal damage of rock slopes with a bi-planar failure. In: Mikoš M, Vilímek V, Yin Y, Sassa K (eds) Advancing culture of living with landslides—landslides in different environments. Proceedings of the 4th World Landslide Forum, 29 May–2 June 2017, Ljubljana. Springer International Publishing, pp 397–405

Bolla A, Paronuzzi P. Numerical investigation of the pre-collapse behavior and internal damage of an unstable rock slope. Rock Mech Rock Eng (Submitted)

Bonzanigo L, Eberhardt E, Loew S (2007) Long-term investigation of a deep-seated creeping landslide in crystalline rock. Part I. Geological and hydromechanical factors controlling the Campo Vallemaggia landslide. Can Geotech J 44:1157–1180CrossRef

Braathen A, Blikra LH, Berg SS, Karlsen F (2004) Rock-slope failures in Norway; type, geometry, deformation mechanisms and stability. Norw J Geol 84:67–88

Brideau M-A, Stead D, Couture R (2006) Structural and engineering geology of the East Gate Landslide, Purcell Mountains, British Columbia, Canada. Eng Geol 84:183–206CrossRef

Brideau M-A, Pedrazzini A, Stead D, Froese C, Jaboyedoff M, van Zeyl D (2011) Three-dimensional slope stability analysis of South Peak, Crowsnest Pass, Alberta, Canada. Landslides 8:139–158CrossRef

Buyuksagis IS, Goktan RM (2007) The effect of Schmidt hammer type on uniaxial compressive strength prediction of rock. Int J Rock Mech Min Sci 44:299–307CrossRef

Carulli GB (2006) Carta geologica del Friuli Venezia Giulia—Scala 1:150,000 con Note Illustrative. Tabacco, Udine, p 44

Chang K-J, Taboada A, Chan Y-C (2005) Geological and morphological study of the Jiufengershan landslide triggered by the Chi-Chi Taiwan earthquake. Geomorphology 71:293–309CrossRef

Chigira M (1992) Long-term gravitational deformation of rocks by mass rock creep. Eng Geol 32:157–184CrossRef

Chigira M (2009) September 2005 rain-induced catastrophic rockslides on slopes affected by deep-seated gravitational deformations, Kyushu, southern Japan. Eng Geol 108:1–15CrossRef

Cloutier C, Locat J, Couture R, Jaboyedoff M (2016) The anatomy of an active slide: the Gascons rockslide, Québec, Canada. Landslides 13:241–258CrossRef

Codeglia D, Dixon N, Fowmes GJ, Marcato G (2017) Analysis of acoustic emission patterns for monitoring of rock slope deformation mechanisms. Eng Geol 219:21–31CrossRef

Cossart E, Braucher R, Fort M, Bourlès DL, Carcaillet J (2008) Slope instability in relation to glacial debuttressing in alpine areas (Upper Durance catchment, southeastern France): evidence from field data and ¹⁰Be cosmic ray exposure ages. Geomorphology 95:3–26CrossRef

Deng QL, Zhu ZY, Cui ZQ, Wang XP (2000) Mass rock creep and landsliding on the Huangtupo slope in the reservoir area of the Three Gorges Project, Yangtze River, China. Eng Geol 58:67–83CrossRef

Eberhardt E (2003) Rock slope stability analysis—utilization of advanced numerical techniques. University of British Columbia, Vancouver

Eberhardt E (2008) The role of advanced numerical methods and geotechnical field measurements in understanding complex deep-seated rock slope failure mechanisms. Can Geotech J 45:484–510CrossRef

Eberhardt E, Thuro K, Luginbuehl M (2005) Slope instability mechanisms in dipping interbedded conglomerates and weathered marls—the 1999 Rufi landslide, Switzerland. Eng Geol 77:35–56CrossRef

Einstein HH, Dershowitz WS (1990) Tensile and shear fracturing in predominantly compressive stress fields—a review. Eng Geol 29(2):149–172CrossRef

Euser B, Rougier E, Lei Z, Knight EE, Frash LP, Carey JW, Viswanathan H, Munjiza A (2019) Simulation of fracture coalescence in granite via the combined Finite-Discrete element method. Rock Mech Rock Eng. https://doi.org/10.1007/s00603-019-01773-0 CrossRef

Fener M, Kahraman S, Bilgil A, Gunaydin O (2005) A comparative evaluation of indirect methods to estimate the compressive strength of rocks. Rock Mech Rock Eng 38:329–343CrossRef

Ganerød GV, Grøneng G, Rønning JS, Dalsegg E, Elvebakk H, Tønnesen JF, Kveldsvik V, Eiken T, Blikra LH, Braathen A (2008) Geological model of the Åknes rockslide, western Norway. Eng Geol 102:1–18CrossRef

Gigli G, Fanti R, Canuti P, Casagli N (2011) Integration of advanced monitoring and numerical modeling techniques for the complete risk scenario analysis of rockslides: the case of Mt. Beni (Florence, Italy). Eng Geol 120:48–59CrossRef

Hoek E (2007) Practical Rock Engineering. http://www.rocscience.com/educational/hoeks_corner. Accessed Apr 2019

Hoek E, Diederichs MS (2006) Empirical estimation of rock mass modulus. Int J Rock Mech Min Sci 43:203–215CrossRef

Holm K, Bovis M, Jakob M (2004) The landslide response of alpine basins to post-Little Ice Age glacial thinning and retreat in southwestern British Columbia. Geomorphology 57:201–216CrossRef

Horii H, Nemat-Nasser S (1985) Compression-induced microcrack growth in brittle solids: axial splitting and shear failure. J Geophys Res 90(10):3105–3125CrossRef

Hungr O, Corominas J, Eberhardt E (2005) Estimating landslide motion mechanism, travel distance and velocity. In: Hungr O, Fell R, Couture R, Eberhardt E (eds) Landslide risk management. Proceedings of the international conference on landslide risk management, Vancouver, BC. CRC Press, Taylor and Francis Group, pp 99–128

ISRM (1978) Suggested methods for the quantitative description of discontinuities in rock masses. Int J Rock Mech Min Sci Geomech Abstr 15:319–368CrossRef

Jaboyedoff M, Penna I, Pedrazzini A, Baroň I, Crosta GB (2013) An introductory review on gravitational-deformation induced structures, fabrics and modeling. Tectonophysics 605:1–12CrossRef

Kahraman S, Fener M, Gunaydin O (2002) Predicting the Schmidt hammer values of in situ intact rock from core sample values. Int J Rock Mech Min Sci 39:395–399CrossRef

Katz O, Reches Z, Roegiers J-C (2000) Evaluation of mechanical rock properties using a Schmidt Hammer. Int J Rock Mech Min Sci 37:723–728CrossRef

Marcato G, Bossi G, Frigerio S, Mantovani M, Pasuto A, Schenato L (2014) Studio e monitoraggio della situazione di dissesto che interessa il versante sinistro del Tagliamento in corrispondenza del “Passo della Morte”. Relazione Finale, Convenzione protocollo n. PC/2805/CD2. Unpublished Report for the Civil Protection of the Friuli Venezia Giulia Region

Martinis B (1985) Il lago quaternario di Forni di Sotto (Alpi Carniche). In: In Alto. Cr. Soc. Alpina Friulana, Udine, vol 47, pp 73–83

Martinis B (1994) Nuovi dati sul lago quaternario di Forni di Sotto (Udine). In: In Alto. Cr. Soc. Alpina Friulana, Udine, Italy, vol. 76, pp 39-44

McColl ST (2012) Paraglacial rock-slope stability. Geomorphology 153–154:1–16CrossRef

Nazir R, Momeni E, Jahed Armaghani D, Mohd Amin MF (2013) Correlation between unconfined compressive strength and indirect tensile strength of limestone rock samples. Electron J Geotech Eng 18:1737–1746

Park CH, Bobet A (2009) Crack coalescence in specimens with open and closed flaws: a comparison. Int J Rock Mech Min Sci 46:819–829CrossRef

Paronuzzi P, Bolla A (2012) The prehistoric Vajont rockslide: an updated geological model. Geomorphology 169–170:165–191CrossRef

Paronuzzi P, Bolla A (2015a) Gravity-induced rock mass damage related to large en masse rockslides: evidence from Vajont. Geomorphology 234:28–53CrossRef

Paronuzzi P, Bolla A (2015b) Gravity-induced fracturing in large rockslides: possible evidence from Vajont. In: Lollino G, Giordan D, Crosta GB, Corominas J, Azzam R, Wasowski J, Sciarra N (eds) Engineering geology for society and territory: landslide processes. Proceedings of the XII international IAEG congress, 15–19 September 2014, Turin. Springer, pp 213–216

Paronuzzi P, Bolla A, Rigo E (2016a) 3D Stress–strain analysis of a failed limestone wedge influenced by an intact rock bridge. Rock Mech Rock Eng 49(8):3223–3242CrossRef

Paronuzzi P, Bolla A, Rigo E (2016b) Brittle and ductile behavior in deep-seated landslides: learning from the Vajont experience. Rock Mech Rock Eng 49(6):2389–2411CrossRef

Pisa G (1972) Geologia dei Monti a nord di Forni di Sotto (Carnia Occidentale). Carta Geologica—Scala 1:20000 con Note Illustrative. Giornale di Geologia. Annali del Museo Geologico di Bologna. Serie 2a, vol XXXVIII, pp 543–688

Prager C, Zangerl C, Patzelt G, Brandner R (2008) Age distribution of fossil landslides in the Tyrol (Austria) and its surrounding areas. Nat Hazards Earth Syst Sci 8:377–407CrossRef

Rocscience (2007) RocData (version 4.0). Rocscience Inc., Toronto

Sandøy G, Oppikofer T, Nilsen B (2017) Why did the 1756 Tjellefonna rockslide occur? A back-analysis of the largest historic rockslide in Norway. Geomorphology 289:78–95CrossRef

Sturzenegger M, Stead D (2012) The Palliser Rockslide, Canadian Rocky Mountains: characterization and modeling of a stepped failure surface. Geomorphology 138:145–161CrossRef

Teza G, Marcato G, Pasuto A, Galgaro A (2015) Integration of laser scanning and thermal imaging in monitoring optimization and assessment of rockfall hazard: a case history in the Carnic Alps (Northeastern Italy). Nat Hazards 76:1535–1549CrossRef

Tomás R, Abellán A, Cano M, Riquelme A, Tenza-Abril AJ, Baeza-Brotons F, Saval JM, Jaboyedoff M (2018) A multidisciplinary approach for the investigation of a rock spreading on an urban slope. Landslides 15:199–217CrossRef

Tsou C-Y, Feng Z-Y, Chigira M (2011) Catastrophic landslide induced by Typhoon Morakot, Shiaolin, Taiwan. Geomorphology 147:166–178CrossRef

Tuckey Z, Stead D (2016) Improvements to field and remote sensing methods for mapping discontinuity persistence and intact rock bridges in rock slopes. Eng Geol 208:136–153CrossRef

Willenberg H, Loew S, Eberhardt E, Evans KF, Spillmann T, Heincke B, Maurer H, Green AG (2008a) Internal structure and deformation of an unstable crystalline rock mass above Randa (Switzerland): part I—internal structure from integrated geological and geophysical investigations. Eng Geol 101:1–14CrossRef

Willenberg H, Evans KF, Eberhardt E, Spillmann T, Loew S (2008b) Internal structure and deformation of an unstable crystalline rock mass above Randa (Switzerland): part II—three-dimensional deformation patterns. Eng Geol 101:15–32CrossRef

Zangerl C, Eberhartd E, Perzlmaier S (2010) Kinematic behaviour and velocity characteristics of a complex deep-seated crystalline rockslide system in relation to its interaction with a dam reservoir. Eng Geol 112:53–67CrossRef

Title: Geomechanical Field Survey to Identify an Unstable Rock Slope: The Passo della Morte Case History (NE Italy)
Authors: Alberto Bolla
Paolo Paronuzzi
Publication date: 24-10-2019
Publisher: Springer Vienna
Published in: Rock Mechanics and Rock Engineering / Issue 4/2020
Print ISSN: 0723-2632
Electronic ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-019-01963-w

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 4/2020

Modeling of Simultaneous Propagation of Multiple Blade-Like Hydraulic Fractures from a Horizontal Well

Effect of Thermal Treatment on the Basic Friction Angle of Rock Joint

Experimental Study on the Effects of Unloading Normal Stress on Shear Mechanical Behaviour of Sandstone Containing a Parallel Fissure Pair

Time-Dependent Propagation of 3-D Cracks in Rocks Under Hydromechanical Coupling

Coupled Physical–Chemical Effects of CO2 on Rock Properties and Breakdown During Intermittent CO2-Hybrid Fracturing

Design of the Key Bearing Layer and Secondary Mining Technology for Previously Mined Areas of Small Coal Mines