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Instability mechanisms affecting cultural heritage sites in the Maltese Archipelago PDF

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Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 Natural Hazards www.nat-hazards-earth-syst-sci.net/12/1883/2012/ and Earth doi:10.5194/nhess-12-1883-2012 ©Author(s)2012. CCAttribution3.0License. System Sciences Instability mechanisms affecting cultural heritage sites in the Maltese Archipelago G.Gigli1,W.Frodella1,F.Mugnai1,D.Tapete1,F.Cigna1,*,R.Fanti1,E.Intrieri1,andL.Lombardi1 1DepartmentofEarthSciences,UniversityofFirenze,Firenze,Italy *Presentaddress: BritishGeologicalSurvey,NickerHill,Keyworth,Nottingham,UK Correspondenceto: G.Gigli(giovanni.gigli@unifi.it) Received: 11October2011–Revised: 9January2012–Accepted: 22January2012–Published: 14June2012 Abstract. The superimposition of geological formations plateausabovethesurroundingcountryside,borderedbyun- withmarkedcontrastingeotechnicalpropertiespresentsone stable steep cliffs. Such a type of configuration evidently ofthemostcriticalenvironmentsforslopeinstabilitydueto generates conditions of high hazard associated with a rele- the different response of the materials to the applied distur- vant vulnerability and related risk for built heritage of sig- bances. Moreover, the above-mentioned geological setting nificant cultural value; threats to people’s safety can derive isoftenassociatedwithhighriskconditions,sincemanyiso- aswell(Cestellietal.,1984;Cotecchia,1997;Canutietal., latedrockslabslocatedatahigheraltitudethanthesurround- 1999;Luzietal.,2004;Egglezosetal.,2008). ingcountrysidehavebeensitesofhistoricaltownsorbuild- Weshouldcarefullydistinguishindetailtheoverallmech- ings. anismwhichgovernsthebehaviorofarockslaboverasoft The purpose of the present paper is to investigate the substratumfromthefailuresthattakeplaceatitsboundaries. mechanisms determining instability in rock slabs overlying Only the latter can be classified according to the traditional a soft substratum, with reference to two cultural heritage landslideclassificationschemes. Theformercanbedefined sitesinMalta. Accurateinvestigationshavebeencarriedout as a complex mass movement, according to Varnes (1978) to evaluate the geological, geotechnical and geomechanical and Hutchinson (1988), since it involves a combination of propertiestogetherwiththemaingeomorphologicalfeatures severaldifferentbasicfailuremechanisms of the soft clayey substratum and the overlying limestone Therefore, the problem requires a multi-disciplinary ap- rockmass. proachinvolvingtheapplicationofprinciplesfromdifferent The main instability processes have thus been identified fields, such as rock and soil mechanics, geology, geomor- and investigated through kinematic analyses and numerical phology,engineeringgeology,andconservationsciences. modeling,combinedwitha1992–2001PersistentScatterers According to Casagli (1992), the instability mechanisms monitoring of ground displacements. The study constitutes affecting this geological environment can be classified into thebasisforthesubsequentrestorationworks. threedifferentbutstrictlyinterconnectedtypes: – overallmechanismofinstability; 1 Introduction – soilslopeinstability; Theoverlappingofhardrockmasses,potentiallysubjectedto – rockslopeinstability. elasticdeformationsandbrittlecollapse,onaplasticsubstra- tum is a common geological feature, especially in cultural As regards the overall mechanism, the contrast in stiffness heritage sites (Cancelli and Pellegrini, 1987; Canuti et al., oftheoutcroppingmaterialscausestheopeningofjointsand 1990,2004; Bertoccietal.,1991; Casaglietal.,1993; Katz newtensilefailures(Casagli,1992);bothisolatelargeblocks andCrouvi,2007). that can be involved in marginal mass movements (Fig. 1). Thissuperimpositionfrequentlyleadstomechanicalinsta- Thefracturingandopeningofjointsproducestressredistri- bilityduetothediverseresponseofthematerialstotheap- bution at the boundary between the rock plate and the sub- pliedperturbations,suchasman-madeexcavations,weather- stratum. Thus,verticalrelativedisplacementsofrockblocks ingorerosion.Thelatteractsselectively,withmajorimpacts may also take place due to local elastic-viscous settlements on the more erodible substratum, thereby forming buttes or andyielding. PublishedbyCopernicusPublicationsonbehalfoftheEuropeanGeosciencesUnion. 1884 G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago presenttheanalysisofthestabilityconditionsoftwoimpor- tantculturalheritagesitesintheMalteseArchipelago:Mdina in Malta and Citadel in Gozo (Fig. 2). Due to their natural and historical importance, both sites are included amongst themaintouristicdestinationsoftheArchipelago. 2 Descriptionofinvestigatedsites 2.1 Maltesegeology Fig.1. Simplifiedsketchoftheinstabilitymechanismsaffectinga rockslaboverlyingasoftsubstratum. MaltaandGozoIslandsbelongtotheMalteseArchipelago, central Mediterranean Sea (Fig. 2a), standing on a shallow submarineelevation, theMaltaplateau, partofthePelagian Associatedwiththesemechanisms,aslowdownwardand Platform (Bowen Jones et al., 1961; Pedley et al., 1978; outwardextrusionoftheclayeymaterialunderlyingtherock Schembri,1993,1997;Magri,2006)(Fig.2b). slab may occur, providing potential material involved in The landscape is geomorphologically characterized by landslidesandearthflows.Thisclassofmovement,knownas gently rolling hills with terraced fields (the highest point of squeezing-out and bulging, is described in detail by Zaruba the archipelago lies at about 250m a.s.l.), while steep sea andMencl(1982). cliffsdelimitthesouth-westerncoastline(Houseetal.,1961; Iftherockplateiswideandthickandthemechanicalprop- Vossmerba¨umer,1972;Alexander,1988). erties of the involved materials are very different, various The geological setting is constituted by marine sedimen- largescaleandslowmovingcomplexphenomenamayoccur, taryrocks,mainlylimestonesOligo-Miocenicinage,subse- knownintheliteratureaslateralspread(Varnes,1978),cam- quentlyliftedabovesealevelduringthePlioceneperiodby bering and valley bulging (Hollingworth et al., 1944; Hor- asubverticalfaultsystemrelatedtotheopeningofthePan- swill and Horton, 1976; Parks, 1991), and block type slope telleria Rift (Reuter, 1984; Finetti, 1985; Alexander, 1988) movements(Pasek,1974). (Fig.2). The overall mechanism of instability also contributes to Amongthefiveunitslyingalmosthorizontallyacrossthe the enhancement of the phenomena, which take place both Maltese Islands (Hyde, 1955; Pedley, 1974; Pedley et al., ontheductilesubstratumandontherockplate. 1976, 1978; Bosenceetal., 1981; DebonoandXerri, 1993; The most common failure mechanisms affecting the un- Pedley, 1993; Pedley et al., 2002) (Fig. 2c), the following derlying soft substratum are rotational or compound slides ones are of particular relevance for the sites of Mdina and (Hutchinson,1988)andearthflows(Varnes,1978;Hungret Gozo: al., 2001). These can also be influenced by the accumula- tionofmaterialwhichhasfallenfromtherockcliff,causing – Blue Clay Formation (BC): a very soft pelagic blue or surcharge(ZarubaandMencl,1982;Casagli,1992). Onthe greenishgreymarlandlimeyclay,rangingfrommiddle otherhand,landslidesatthebaseoftherockslabundermine to upper Miocene in age, forming gentle hillslopes underlyingsupportandtriggerfurtherblockmovements. mostlycoveredbysoilorscatteredrubble. Itsthickness Thesubverticalandjointedrockwallscanbeaffectedby variesapproximatelyfromabout20mto75m. agreatvarietyofmechanisms,suchasrockfalls,rockslides, toppling(eitherforwardorbacktilting),anddifferentialset- – Greensand Formation (GS): massive, friable brown tlements. Rock slope failure at the border of the slab in- to dark green glauconite and gypsum grain-rich bio- creases the stress relief, and causes the spread of the insta- clastic limestone, Tortonian in age. This formation is bilityphenomena. rarely more than 1m thick, and can occasionally ex- Thegreatvarietyofinterconnectedinstabilitymechanisms pandtoover10matthebaseofhilltopsincentralGozo. affecting a rock plate – soft substratum system is therefore abletoproducegreatdamagetostructuresorbuildingsbuilt either on the rock plate or at the base of the rock walls – Upper Coralline Limestone Formation (UCL): over (Fig.1). 160m thick, it consists of pale grey to orange fossil- The geological setting of the Maltese Archipelago often iferous coarse grained limestone, ranging from upper showstheoverlappingofrelativelystiffandbrittlelimestone Tortonian to early Messinian in age, and it is made up plates on thick clayey units. This leads to typical geomor- of four members, the basal one of which is referred to phological processes, such as slides or flow phenomena in asGhajnMelelMember(Mgm). theunderlyingductileunitsandbrittlerupturesinvolvingthe overlyingrockmasses. Thelatterareoftenaffectedbyhuge sub-verticaljointsthatisolatelargeblocks. Inthispaperwe Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 www.nat-hazards-earth-syst-sci.net/12/1883/2012/ G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago 1885 1 2 Figure 2 Fig. 2. Geog3ra phic setting (A), simplified geological map (B) and stratigraphic column (C) of the Maltese Archipelago (modified after Pedleyetal.,420 02) . UCL hillcaps and plateaus overtopping BC gentle slopes erosionofthelandthatsurroundsthem(Scerri,2003). Allof are the dominant feature in the landscape of north-western them are characterized by sub-horizontal or gently inclined Maltaandnorth-easternGozo(Fig.3a,b).Therefore,thege- UCLcapprotectingtheunderlyingsoftBCslopes.Although ologicalandgeomorphologicalfeaturesofthelatterareasare the geological materials and the stratigraphic sequences are deeply influenced by the geological characteristics and mu- similar, the investigated sites show quite diverse instability tualinteractionoftheabove-mentionedformations(Magriet problems, due mainly to the different thickness of the out- al., 2008; Devoto et al., 2011), while GS, due to its limited croppingformationsandtospecificgeologicalfeatures. thickness,canonlyaffecttheformofthelandsurfacelocally. UCL,beingatthetopoftheMalteseIslandsstratigraphic sequence, is particularly subjected to the action of eroding 2.2 Geologicalsettingoftheinvestigatedsites factors: percolatingrainwaterdissolvesthelimestone,form- 28 ing fissures and caves, stopping when it reaches the imper- MdinaandCitade l(Fig.3c,d)arebuiltontwohillsbelong- meable barrier of the underlying BC. When the contact of ing to the many that characterize the Maltese and Gozitan thesetwounitsmeetsthelandsurface,springlinesmayde- landscapes. These reliefs owe their existence to the deeper velop, contributing to undermining the limestone hillcaps’ www.nat-hazards-earth-syst-sci.net/12/1883/2012/ Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 1886 G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago A B C D Fig.3. PanoramicviewsofUCLslabsoverlyingBCexposedinGozo(A)andMalta(B),andoftheinvestigatedsitesofMdina(C)and Citadel(D). stability. Furthermorerainfallwashesawaytheeasilyerodi- rockplate,thestructuresareoftenbuiltoverthecontactbe- bleBCcausingtheovertoppinglimestonecapstobreakaway tween the UCL/GS and the underlying BC, thus increasing andcollapseintoblocksofvarioussizes(Fig.3d)(Pedleyet theinstabilityproblemsduetodifferentialsettlementsofthe al.,2002). structures. Forthisreason,mostofthedamagetobuildingsandbas- 2.3 Mdina tion walls is located in the perimetral sectors of the city (Baratin et al., 2001; Bonnici et al., 2008) (Fig. 4), and is Mdina, the former capital of Malta, is a fortified town lo- concentratedinthreespecificareas,namelyVilhenaPalace, cated in the central – western sector of the Island on a rise CathedralandCurtainMagazines. constitutedbytheUCL(Fig.3c). Thankstoitsstrategicpo- sition,overthepastcenturiesthecityhasbeeninfluencedby 2.4 Citadel many cultures. In 1693 it was extensively damaged by the Val di Noto (Sicily) earthquake (Galea, 2007), and most of Citadelisasmallfortifiedtown(Fig.3d)locatedinthecen- the buildings and bastions were constructed afterwards (De tralpartofGozo,onahilltoplocatedabovethetownofVic- Lucca, 1993). The city is built on a thin UCL plate (max- toria(alsoknownasRabat). Givenitscentralandpanoramic imum thickness: 6m) with a rhomboidal shape and a total location within the island of Gozo, this vantage point has surfaceareaofabout55000m2. hostedurbansettlementssincetheBronzeAge. From a geomorphological point of view, the main land- ThehillconsistsofmoreorlesscircularUCLrockplate, formsassociatedwiththegeologicalsystemdescribedabove whichis20mto25mthickandabout150mwide,overlying are always hidden by anthropic structures, and can only be firstalayerofGSandthengentleBCslopes. observed on the nearby hills, where the landscape is much The rock plate slopes are sub-vertical, sometimes lessmodifiedbyhumanactivities. Duetothethinnessofthe overhanging, while the underlying slopes are mostly Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 www.nat-hazards-earth-syst-sci.net/12/1883/2012/ G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago 1887 Fig.4.StructuraldamagesaffectingMdinabastions,wallsandbuidings.(A):St.Paul’sBastion;(B)and(C):VilhenaPalace;(D):Despuig Bastion. Fig.5.InstabilitymechanismsaffectingtheUCLrockplateunderlyingCitadel(A:rockmassandunderpinningmasonry;B:rockfalldebris). www.nat-hazards-earth-syst-sci.net/12/1883/2012/ Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 1888 G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago AREA C BC2!CCC!C021!!8!CC!!11C!1!C7!C54 B!6 BB!42!!BB!1!3BB!42 AREA B C!4C!3C!9C!!9 B!5! B!3 C6 B6 B’ Landslide Upper Coralline Limestone A1!A!2 A!3 ! Blue Clay ! A4 Globigerina Limestone A12! A3A!5 SHcoarirzpontal strata ± A7!!A6 SL 1 A!2 GGeeoomlogeicchaal ncircoasls s-csaenctliinoens (SL) A11!A1!0!A1A9!!A8 AREA A ! Vertical boreholes SL 2 ! 01020 40 60 80 (m) Inclined boreholes 240 240 230 Cathedral 230 220 220 210 Triq San PietruTriq IL-Villegianon 210 200 Curtain Magazine 200 190 C7 C5 Despuig Bastion 190 180 C1 B5 B4 180 170 B3 170 160 160 150 150 (m) (m) B 0510 20 30 40 (m) B’ E/NE W/SW Fig. 6. Geological map and cross-section of Mdina. Area A: Vilhena Palace; Area B: Cathedral and Despuig Bastion; Area C: Curtain Magazines. characterizedbyverygentletogentlesteepness(from10% From a structural point of view, although extensive ev- to20%). idence around the fortification walls shows rebuilding of The rock mass shows a high degree of fracturing, and is structures due to cliff face retreat, the only signs of defor- constituted by layers having different resistance to erosion, mation are related to differential displacements of the few leadingtotheformationofledgesandniches(Fig.5a);these structuresbuiltonthecontactbetweendifferentmaterials. factors cause the detachment and falling of rock blocks of varioussizes.Onthenorthernsectorofthecliff,alargerock- falleventtookplaceinDecember2001,andtheresultingde- 3 Datacollection brisisstillevident(Fig.5b). Evidenceofpreviousrockfallsisalsovisibleslightlyeast 3.1 Geologicalsurvey totheeventwhichoccurredin2001. Inordertoinhibitthese Accurate geological, geomorphological and geomechanical rockfallsseveralunderpinningmasonrystructureswerebuilt surveysoftheselectedsiteswerecarriedoutwiththeaimof in the past, with the purpose of protecting the niches which investigatingthecausesofthemaininstabilityprocessesand are the most eroded portions of the outcropping cap rock, determiningthematerialpropertiestobesubsequentlyused andtoimproveitsglobalstability. Thesestructures, widely duringtheanalysisphase. presentonthenorthernandeasternsideofthecliffface,were builtindifferentperiods,andmanyofthemarenowinapoor Inparticular, highresolutiongeologicalmapsandrelated stateofrepair(Fig.5a). cross-sections were drawn utilizing the detailed geological survey,carriedoutbymeansofadifferentialGPSsurvey,in Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 www.nat-hazards-earth-syst-sci.net/12/1883/2012/ G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago 1889 ± Upper Coralline Limestone j20 Strata dip direction Geomechanical scanlines (SL) ! Greensand Interpreted fault Vertical boreholes ! Blue Clay Geological cross-section Inclined boreholes j A d ej ! ! 17 fj j !SL 5 30 ! b 20 SL 4c! ! 1a5!SL g! jA B ! 6 ! 17 L 3 C 2j0 j S 20 j j TTTeTeexexxtxtttText 20 D ! 12 20 jL 2 S TeTTxeetxxtt S j18L 1 E!18j j j20 j28 16j 16 15j A’ 0 10 20 40 60 80 (m) 150 Triq San Guzepp Cathedral 150 140 B Triq Bieb l’Imbina 140 130 130 Ditch 120 120 110 E 110 100 100 (m) (m) A 0 510 20 30 40 (m) A’ NW SE Fig.7.Geologicalmapandcross-sectionofCitadel. order to reconstruct, with centimeter accuracy, the 3-D ge- Furthermore,ageotechnicalcharacterizationhasalsobeen ological model and its geometric correlation with the man- carriedoutbymeansoflaboratorytestsonundisturbedrock madestructures. and soil samples retrieved from the deep and inclined bore- The traditional geological surveys have been integrated holes(Tapeteetal.,2012). with a number of ground (deep vertical boreholes; Figs. 6 and 7) and structural investigations (horizontal and inclined As regards Mdina the stratigraphic contact between the boreholes), carriedoutbyBallutBlocksServicesLtd.(Md- UCLandtheunderlyingGSandBCisnotregular,andsome ina)andSolidbaseLtd.(Citadel). groundwateremergesontheclayeyslopesintheformofmi- nor springs along the scarps. The location of these minor www.nat-hazards-earth-syst-sci.net/12/1883/2012/ Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 1890 G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago Fig.8.Discontinuitypoles,contourlinesandmodalplanesofthemaindiscontinuitysetscollectedatMdina(A)andCitadel(B).Themean buriedrock-slopeorientationoftheMdinaareasinvestigatedisalsoreported(redmajorplanes). springsisusuallymarkedbythegrowthofmanyhydrophilic ite, shows persistent subvertical fissures and joints, which plants(suchasreeds). Groundwaterseepingoutatthebase have triggered many rockfalls occurring along the cliff face of the plateau scarps in the form of gravity springs desta- perimeter. For its different internal sedimentary fabric and bilizes the clay which then undermines the plateau. This reactiontoerosion,ithasbeensubdividedintothreedistinct processaffectsthescarpreducingshearstrengthandmakes informalsub-members,whichfromtoptobottomare: itpronetoshearfailureundertheactionofgravity. Figure 6 reports the high resolution geological map and – UpperBank: havingamassivestructure,isdirectlylo- a representative cross-section for the Mdina site. Vilhena catedatthebaseofthebastionwalls. Itischaracterized Palace (Area A), the Cathedral (Area B) and the Curtain byarelativelystrongresistancetoerosionandtoweath- Magazines(AreaC),whichdisplaythemostevidentinstabil- eringprocesses. ityproblems(Fig.4),areshownwithwhitecirclesinFig.6. – ThinlyLayeredBank: itunderliestheUpperBank,dif- The limestone bedding planes are parallel and almost hori- fering from the latter for a thinly layered structure and zontal. Here the GS formation is characterized by a mini- formuchlessresistancetoerosion. Infactitgivesform mal thickness (few centimeters), which makes it difficult to toerosionalniches,oftencoveredbyunderpinningma- show on the map, and irrelevant with respect to the global sonrystructures. slope stability. The geological cross-section also highlights thethinnessoftheUCLrockplate,beingalmostcompletely – LowerBank:itconsistsofthelowerportionoftheMgm coveredwithman-madestructures.Thiscausesseriousinsta- Member,overlyingtheclifffacebaselevelofGS.Sim- bilityproblemsduetodifferentialsettlementsofthosestruc- ilartotheUpperBankitshowsamassivestructureand tures built over the rock-clay contact. Figure 6 also reports arelativelystrongresistancetoerosion. Itissometimes the upper boundary of an area involved in a slope instabil- coveredbyvegetationandrubblewhichlimitsitsexpo- ity process, as observed from field surveys and from aerial sure. images. Thislandslideissupposedtoplayasignificantrole inthestructuralinstability, underminingthelimestoneplate Thestrataorientationscollectedallaroundthecliffshowthat rightintheCurtainMagazine(AreaC)foundationarea. the bedding planes always dip into the slope from the cliff As regards Citadel (Fig. 7), the rock outcrops of the cliff perimetertowardsthecentreoftherockplate, withinclina- facearealmostentirelyconstitutedbyUCL,hererepresented tion angles ranging from 12◦ to 30◦ (Fig. 7). According to bytheGhajnMelelMember(Mgm),withtheexceptionofa Pedley(1974)thisstructuralsettingisduetoasolutioncol- GSlayeratthebaseofthehillcap. Fromtheanalysisofthe lapse structure, late Miocene in age, like many others scat- retrieved borehole cores, this GS layer is about 10m thick teredallovertheMalteseislands. WherethethickMiocene (Fig.7);thisvalueiscomparabletothethicknessofthesame infill is softer than the surrounding materials, an erosional FormationoutcroppingatGelmusHill,lessthan1kmWNW hollowiscausedbyselectiveerosion;insteadwhentheinfill fromCitadel. isharderthanthesurroundingmaterials,becauseofahigher The Ghajn Melel Member (Mgm), mainly consisting of degreeoflitification,acircularerosionalplateau(mesa)oc- a yellow to pale brown coarse grained organic calcaren- curs(Pedleyetal.,2002). Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 www.nat-hazards-earth-syst-sci.net/12/1883/2012/ G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago 1891 Table 1. Geomechanical properties of the rock mass discontinuities. Set id: joint set identification code; α: dip direction; β: dip; X: truespacing;L:persistence;e: aperture;JRC:JointRoughnessCoefficient;JCS:JointCompressiveStrength;r: Schmidthammerrebound numberonwetandweatheredfracturesurfaces;R:Schmidthammerreboundnumberondryunweatheredsurfaces;φb:basicfrictionangle. Set id α(◦) β(◦) X(m) L(m) e(mm) JRC JCS r/R φb(◦) JN1 272 75 3.5 1.3 9.8 11.1 18.3 0.4 32.3 JN2 104 76 7.0 1.6 15.3 12.8 17.4 0.5 32.3 UCLMdina JN3 314 81 5.4 1.6 15.6 14.6 21.7 0.7 32.3 JN4 075 76 7.8 1.5 21.4 13 20.1 0.5 32.3 JN1 030 89 1.4 2.5 13.3 12.1 15.6 0.4 35.9 JN2 274 84 1.3 2.9 12.9 11.7 17.5 0.8 35.9 UCLCitadel JN3 329 73 5.1 2.6 17 13.7 16.9 0.6 35.9 BG 0–360 12–17 1.4 Inf. 11 12 15.7 0.7 35.9 3.2 Geomechanicalsurvey stratification, four main sets can be identified on the rock massunderlyingMdina. Therockmasscharacterizationandthequantitativedescrip- Fourdiscontinuitysetshavealsobeenidentifiedwithinthe tionofdiscontinuitieswereobtainedbymeansoftraditional rockslabunderlyingCitadel(Fig.8b). geomechanical surveys (scanline method), according to the Both sites show medium pole dispersion, with a preva- methodssuggestedbytheInternationalSocietyforRockMe- lence of high dipping discontinuity planes (excluding the chanics(ISRM,1978,1985). beddingplanes). DuetothelimitedrockmassoutcroppingatMdina, only Thesestructuraldatawereemployedinthekinematicanal- 2scanlinesurveys(25mand30minlength)wereperformed ysesandnumericalmodelling,describedinSect.4. on the rockwall next to the ditch within the Vilhena Palace Theshearstrengthofdiscontinuitieswascalculatedusing area (Area A) (Fig. 6). In order to extend the rock mass Barton’s failure criterion (Barton and Choubey, 1977). Fi- mechanical properties to the other investigated areas, some nally,foracompletecharacterizationofthematerialproper- randomdiscontinuityorientationmeasurementsweretaken, ties to be used in the numerical model, the Mohr Coulomb confirmingthespatialdistributionoftheidentifieddisconti- equivalentstrengthparametersoftherockmasswerecalcu- nuitysets. lated through the Hoek and Brown failure criterion (Hoek andBrown,1980;Hoeketal.,2002). Thesepropertieswere As regards Citadel, a total of 6 scanline surveys (varying usedasinputparametersforthekinematicanalysesandnu- from 15m to 33m in length) were performed according to mericalmodelling(Table1). themethodssuggestedbyISRM(1978, 1985). Thesescan- lineswereperformedallaroundthecliffface,tocoverboth 3.3 Laserscanningsurvey themassiveUpperandLowerBankandtheThinlyLayered BankoftheGhajnMelelMemberwithintheUCLFormation Nowadays, advanced techniques are available for obtaining (Fig.7). high resolution 3-D representations of land surface, such as Foreachscanlineasheetwasfilledbymeasuringtheori- digital photogrammetry (Chandler, 1999; Lane et al., 2000) entation,persistence,aperture,roughness,rockwallstrength, and laser scanning (both terrestrial and aerial) (Kraus and filling,seepageofthediscontinuitiescrossingthesurveyline. Pfeiffer,1998;FrohlichandMettenleiter,2004). InordertodeterminetheUCLintactrocktensileandcom- Themainproductofalongrangelaserscanningsurveyisa pressive strength for both investigated sites, a number of highresolutionpointcloud,obtainedbymeasuringwithhigh pointloadtestswereperformed,followingthemethodssug- accuracy(millimeterorcentimeter)thedistanceofameshof gested by ISRM (1985). The resulting σ values for UCL c points on the object, following a regular pattern with polar intactrockare: 22.3MPa(Mdina)and6.7MPa(Citadel). coordinates. The high acquisition rate (up to hundreds of With the aim of identifying the major discontinuity sets, thousands points per second) makes the detailed 3-D shape orientation data were plotted on a stereographic projection oftheobjectimmediatelyavailable. (lowerhemisphere). The advantage of employing remote and high resolution Figure 8a reports the stereographic projection of the col- surveyingtechniquesisthatitallowsustoperformdetailed lected data: discontinuity poles concentration, main set analyses and to rapidly obtain information on inaccessible modal planes and mean buried rock-slope orientation in the rock exposures. This is very important in the field of en- investigated areas are shown. Excluding the sub-horizontal gineering geology and emergency management, when it is www.nat-hazards-earth-syst-sci.net/12/1883/2012/ Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 1892 G.Giglietal.: InstabilitymechanismsaffectingculturalheritagesitesintheMalteseArchipelago A B Fig.9. LaserscannerinactionatVilhenaPalace,Mdina(A);Truecoloured3-DpointcloudofVilhenaPalace,Mdina(B). N Mtarfa Mdina A B Fig. 10. (A): Example of ERS2 image acquired along descending orbit on the Maltese Archipelago (displayed in terms of amplitude). Footprintofthewholesceneisshownwithintheinsetasadashedblackpolygon. (B):Subsetof(A)displayedinSARcoordinatesand includingtheurbanareaofMtarfaandMdina. often advisable to minimize survey time in dangerous envi- tures and the slopes, making it possible to reconstruct the ronmentsandatthesametimegatheralltherequiredinfor- plano-altimetric relationship between the local geology and mationasfastaspossible. theman-madestructures(Figs.6and7). Thankstothehigh The Laser Scanning technique is being more frequently resolution of the laser scanning survey we can also extract used for instability analyses in cultural heritage sites even the smallest features, such as the structural crack pat- (Boehler et al., 2001; Arayici, 2007; Lambers et al., 2007; tern, the crack opening direction (Gigli et al., 2009), and Yastikli, 2007; Yilmaz et al., 2007; Al-kheder et al., 2009; theorientationofcriticaldiscontinuitieswithintherockmass Fanti et al., 2011, 2012), as it allows detailed and high ac- (GigliandCasagli,2011). curacy3-Drepresentationofboththeunderlyinggroundand A laser scanning survey of the investigated Mdina areas theoverlyingstructuresinashorttime. was carried out, by employing a long range 3-D laser scan- A detailed 3-D model of the investigated sites is useful ner (RIEGL LMSZ410-i) (Fig. 9a). This device can deter- for building a complete digital model including the struc- minethepositionofupto12000pointss−1withamaximum Nat. HazardsEarthSyst. Sci.,12,1883–1903,2012 www.nat-hazards-earth-syst-sci.net/12/1883/2012/

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a soft substratum, with reference to two cultural heritage sites in Malta. Accurate investigations have been carried out to evaluate the geological, geotechnical and geomechanical properties together with the main fields, such as rock and soil mechanics, geology, geomor- phology, engineering geolo
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