Geophys.J.Int.(1999)137,891–908 Microseismicity and focal mechanisms at the western termination of the North Anatolian Fault and their implications for continental tectonics Denis Hatzfeld,1 Maria Ziazia,2 Despina Kementzetzidou,1 Panayotis Hatzidimitriou,3 Dimitris Panagiotopoulos,3 Kostas Makropoulos,2 Panayotis Papadimitriou2 and Anne Deschamps4 1LaboratoiredeGe´ophysiqueInterneetTectonophysique,IRIGM-CNRS,BPP53X,38041GrenobleCedex9,France. E-mail:[email protected] 2DepartmentofGeophysics,UniversityofAthens,Ilissia,15784Athens,Greece 3GeophysicalLaboratory,AristotleUniversity,BP352–01,54006Thessaloniki,Greece 4Ge´osciences-Azur,250av.AlbertEinstein,06560Valbonne,France Accepted1999January29.Received1998October10;inoriginalform1997December3 SUMMARY For seven weeks, a temporary network of 68 seismological stations was operated in Central Greece, in the region of Thessaly and Evia, located at the western termination of the North Anatolian Fault system. We recorded 510 earthquakes and computed 80 focalmechanisms.SeismicactivityisassociatedwiththeNE–SWdextralNorthAegean Fault,orwithveryyoungE–W-strikingnormalfaultsthatarelocatedaroundtheGulf of Volos and the Gulf of Lamia. The important NW–SE-striking faults bounding the Pilion,orthebasinsofLarissaand Karditsa,are notseismically active,suggestingthat itiseasiertobreakcontinentalcrust,creatingnewfaultsperpendiculartotheprincipal stresses, than to reactivate faults that strike obliquely to the principal stress axes Key words: continental deformation, faulting, microearthquakes, seismotectonics. and requires extension of approximately that amount within INTRODUCTION the Aegean(Noomenet al.1995). Continental deformation is commonly more complicated TheNorthAegeanregionisaVectedbyintensedeformation. than plate tectonics predicts, for it is not limited to narrow The seismicity is relatively high and defines a limited number boundaries between rigid lithospheric plates, but aVects wide of active features (Fig.1). The most prominent is the North areas with horizontal dimensions much larger than the litho- Aegean Trough, which formsone ofthe three branches ofthe sphere thickness (England & Jackson 1989). The strength of western continuation of the North Anatolian Fault (Lyberis continentallithosphereappearstobelessthanthatofoceanic 1984; Jackson & McKenzie 1988; Taymaz et al. 1991). In lithosphere, in part because most continental regions have contrast, in the southern Aegean (Peloponnese, Sea of Crete, beenaVectedbyprevioustectonicevents.Crustalblocksmove DodecaneseandCycladesislands),extensionof~1.0–1.5cmyr−1 relativetooneanothergenerallyinacomplexkinematicscheme, occurs nearly parallel to the Hellenic Trench (Noomen et al. and the origins of the forces that drive the crustal blocks still 1995, Robbinsetal. 1994;Kastens etal. 1995). remain a matter of debate. To what extent does the upper Severalgeodynamicalmodelshavebeenproposedtoexplain crust passively respond to the motion of a ductile lower the deformation and the kinematics of the North Aegean. crust and upper mantle (e.g. England & McKenzie 1982; Some models imply one (McKenzie 1972) or two (Le Pichon Molnar 1988; Lamb 1994), or to forces applied to its edges et al. 1995) small rigid lithospheric plates that move relative (e.g.Tapponnier1977; Nuretal. 1986)? to Eurasia. Others include crustal blocks of smaller size (e.g. TheAegeanregion(Figs1and2)isoneofthemostrapidly McKenzie & Jackson 1983; Taymaz et al. 1991) that interact deforming regions in the continental domain (Jackson 1994; over aviscoplasticsubstratum(e.g. England etal. 1985). Papazachos & Kiratzi 1996). Although located between the Insomemodels,thegeodynamicsoftheAegeanisgoverned two major lithospheric plates of Eurasia and Africa, whose bythemotionofArabiaandTurkeyrelativetoEurasia,which 1cmyr−1convergentmotionisapproximatelyN–S(McKenzie implies a synchronous motion for both the North Anatolian 1972, 1978; De Mets et al. 1990), the Hellenic Trench moves Fault andthe Aegean.However, the extensionthataVectsthe southwestwards at about 3.5cmyr−1 with respect to Eurasia Aegean region began a least 15Myr ago and therefore it is ©1999RAS 891 892 D. Hatzfeld et al. Figure1. General sketch of the Aegean showing seismicity and geographical names. White dots mark locations of earthquakes of magnitude greaterthan4.5from1963to1996locatedbytheNEIS.ThewhitearrowshowsthemotionofAegearelativetoEurope.Theboxsurroundsthe areastudiedhere. earlier than the Upper Miocene start of motion along the SEISMICITY AND TECTONICS NorthAegeanTrough(Angelieretal.1982;Mercieretal.1989; Jolivetetal. 1994).Therefore,the geodynamicsof the Aegean The North Aegean Trough follows the western continuation seemstobeindependentof(oronlyweaklydependenton)the of the dextral strike-slip North Anatolian Fault, which in movement of Anatolia (Le Pichon et al. 1995). McKenzie & western Turkey, before entering the North Aegean Sea, splits Jackson(1983)proposedthattheNE–SWright-lateralstrike- intothreebranches(Taymazetal.1991).Thenorthernbranch slip motion on the North Aegean Trough is taken up on a is the most seismically active(Figs 1 and 2) and is associated wide zone of normal faulting that is responsible for block withanimportantbathymetricfeatureconnectedtotheSaros rotations.Pavlides&Caputo(1994)suggestedthattheNorth and Sporades basins with a depth of 1500m (Lyberis 1984), Anatolian Fault propagated southwestwards into the Aegean. whichwerereactivatedduringPliocenetime(Dinter&Royden Armijo et al. (1996) proposed that this fault is deeply rooted 1993). In contrast, the southern branch is less developed, the in the lithosphere and that its propagation is responsible for associated basins are not as deep, and the amount of motion the recent increase of tectonic activity in the pre-existing rifts along the fault zone is probably smaller (Mascle & Martin of the North Evia Basin, the Gulf of Evia and the Gulf of 1990). Corinth.ThisincreaseofactivityintheGulfofCorinth1Myr AllthreebranchesoftheNorthAegeanFaultstopabruptly agoissynchronouswithachangeindirectionoftheextension at the Saros and Northern Evia basins. No well-defined that is documented in most of the Northern Aegean region tectonicstructureresponsibleforthetransferofmotiontothe such as the Mygdonia graben (Mercier et al. 1983), western GulfofEviaandtheGulfofCorinthhasbeenrecognized.The Macedonia (Pavlides & Mountrakis 1987) and Thessaly Sarosand Eviabasinsare bounded,east ofPilion andeast of (Caputo&Pavlides1993). Evia, by very important NW–SE-striking faults that were Inthiscontext,westudiedtheseismotectonicsofthewestern activeduringPliocenetime(Caputo1990;Roberts&Jackson termination of the North Aegean Trough and its relationship 1991; Armijoetal. 1996). with the tectonics of continental Greece in order to address The tectonics of continental Greece underwent changes the questions related to the tectonics (active faulting) and in late Cenozoic time that varied from region to region. kinematics (both in space and in time) of this area and infer In Thessaly, after the orogenic compressive episode that itspossibledynamics. aVectedwesternGreeceduringtheEarlyMiocene,twodiVerent ©1999RAS,GJI137,891–908 Microseismicity around Volos (Greece) 893 Figure2. Mapshowinglower-hemisphereprojectionsoffocalmechanismscomputedinthenorthwestAegeanregionforteleseismicdata.Black andgreyquadrantsincludecompressionalfirstmotionsformechanismsmodelledbyTaymazetal.(1991)andHarvardCMTsolutions,respectively. Figure3. MapofthetemporaryseismologicalnetworkinstalledinThessalyandLocridduringthesummerof1992forsevenweeks.Thelocations ofhistoricalearthquakes(Papazachos&Papazachou1997)andofearthquakeswithmagnitudesgreaterthan4.5(NEIS)areshownbyboxesand circles,respectively.Thesmokedpaperanddigitalseismologicalstationsareshownbyopenandfilledtriangles,respectively. ©1999RAS,GJI137,891–908 894 D. Hatzfeld et al. extensionphasesareobserved.Thefirstextensionphase(Late upgoingrays.Amongthe80focalmechanisms,22(categoryA) Miocene–Pliocene), possibly due to post-orogenic collapse, had three quadrants sampled and the azimuth of both planes trendedNE–SW(Mercieretal.1976,1979;Caputo&Pavlides was constrained to within 10°, 27 (category B) had one plane 1993) and created the two important basins of Larissa and constrainedtowithin10°andtheothertowithin20°.Forthe Karditsa. The second extension phase, trending N–S, started remaining 31 (Category C), we relaxed the criteria regarding in the Middle Pleistocene and activated many E–W-striking thequadrantsandthereforethefaultplanesvariedbyasmuch faults. The later episode is certainly the less well developed, as 30° but they still gave an indication of the type of faulting with extension of only ~1mmyr−1 (Caputo 1995, 1996; (strike-slip,normalor reverse). Caputo & Pavlides 1993). To the south, the tectonics are dominatedbylargefaultsstriking WNW–ESEthatdip either RESULTS totheNEortotheSW,andareresponsiblefortheformation of important basins such as the Gulf of Evia and the Gulf Withatimespanofonlysevenweeks,thefewhundredevents of Corinth (Mercier et al. 1976; Roberts & Jackson 1991). that we located may not be representative of the long-term Microtectonicobservationssuggestthatmotionisdiachronous deformation. Their virtue, however, lies in the fact that their onthesamefault(Philip1976).DuringthePliocene,extension locations are much more accurate than those recorded only trendedNE–SWasinThessaly,butduringtheQuaternarythis byteleseismicorregionalstations.Toensurethatourdatawere orientationchangedtoNNW–SSEwithasmallcomponentof representative, we smoothed our locations and mechanisms strike-slipmotiononthe faults. over a scale consistent with regional tectonics and compared ThereisstrongevidencethatcontinentalGreeceunderwent our data with those of stronger (historical and teleseismically extension with a direction variable in time. Most of the computed) events in the area. The magnitudes of the earth- importanttectonicstructuresareduetotheNE–SW-trending quakes ranged from 0.4 to 4.5 with a maximum number of Pliocene extension which generated basins bounded by faults events around magnitude 2.0. The depths of the earthquakes striking NW–SE, but this extension changed to N–S or rangedbetween thesurfaceand 34km, butthegreat majority NNW–SSE during the Quaternary, and it is probably still were locatedatadepthshallower than15km. active,asattestedbyseismicity.Thischangeintheorientation The lack of subcrustal seismicity, even over such a short is also seen on a few islands of the Northern Aegean Sea period of time, concurs with the inference that the northern (Mercier et al. 1989; Pavlides & Tranos 1991) which are extentofHellenicsubductionlieslargelysouthofournetwork. crossedby largestrike-slip-motionactivestructures. During a previous microearthquake study, we located some events at depths greater than 120km beneath southern Evia (Hatzfeld et al. 1990). Reliable teleseismically located inter- DATA mediateseismicityalsostopsbeneathsouthernEvia(Hatzfeld Duringthe summerof1992(fromJuly1untilAugust25),we &Martin1991).Therefore,itislikelythatintermediate-depth operated a temporary network of portable stations covering seismicity related to the Hellenic slab does not extend to the southern Thessaly, Locrid, northern Evia and the islands of northofEvia. Skiathos,Skopelos and Alonissos.The purpose of this was to Theshallowseismicityisnotuniformlydistributedthrough- study the seismicity and focal mechanisms of the area and outtheregion.WeobserveaclusterassociatedwiththeNorth theirconsistencywiththesurfacetectonicstructures,especially Aegean Trough, where the strongest event (magnitude 4.5) for northern Evia and Locrid (Fig.3). The network consisted occurred during the experiment. We observe clusters also of 68 stations, 62 of them recorded on smoked paper using around the Gulf of Volos, the Pindus boundary, the Gulf of 1Hz vertical seismometers, and six of them Lennartz digital Evia and the Gulf of Corinth, which is located outside our recorders connected to 1Hz 3-D seismometers. The average network.NotetheslightdiVerencebetweenlocationsfromthe spacing between stations was less than 15km in order to International Seismological Center (NEIS) (Fig.3) and our ensureaccurateestimationsofthefocaldepthsforcrustalevents locations (Fig.4),especiallyaround Evia andeast Locrid. andtoallowagoodcoverageoffirst-motionpolaritiesonthe In the following, we describe our results in detail, region focal sphere. All internal clocks were calibrated periodically byregion. with a DCF radio telemetered time code, and we believe the time to be accurate to within 0.1s. For the strongest events TheNorthAegeanTroughandtheSporadesBasin we also used the permanent stations of the University of Thessaloniki. This region lies outside our network. Because the strongest More than 9000 P+S phases allowed us to locate 510 event(Md>4.5)andtherelatedaftershockswerealsorecorded earthquakes recorded by more than four stations (Fig.4). by the permanent network of the Aristotle University of Details of the procedure used to determine the velocity Thessaloniki, we could determine more precise locations than structure and the Vp/Vs ratio, to locate the earthquakes and would have been possible with our network alone and we to select the most reliable events are discussed in Hatzfeld computedfault planesolutions forsomeoftheseevents. et al. (1990). The velocity structure for the Northern Aegean The seismicity is distributed in two main clusters (Figs 5 Sea diVers from that for continental Greece (Table 1). The and 6). The northern cluster lies between the Sporades Basin computedVp/Vsratiois1.78.Amongtheearthquakesthatwe and the Saros Trough. Relative to the surrounding high- located, uncertainties in epicentre and depth for 318 of them bathymetryareas(LePichonetal.1985),thistroughisactually werelessthan5km,andfor246lessthan2km.Themagnitude averynarrowanddeep(greaterthan6000m)basinfilledwith wascalculatedusing thecoda duration(Lee& Lahr1972). Neogene sediments and constitutes the easterntermination of Focal mechanisms were computed for earthquakes that the Sporades Basin (Le Pichon et al. 1985). Seismic activity were recorded with more than eight first-motion polarities of followsthedirectionofthisnarrow,deepbasinandisconsistent ©1999RAS,GJI137,891–908 Microseismicity around Volos (Greece) 895 Figure4. Mapshowingthe510epicentresthatwelocatedwithourtemporaryseismologicalnetworkduringthesummerof1992. with the longer-term seismicity mapped with NEIS data. The the southern termination of the Pilion peninsula. Therefore, focalmechanismscomputedforthemagnitude4.5earthquake thestrike-slipeventsareunlikelytoberelatedtotheimportant of July 23 (#127) and its aftershocks (#128, 130, 131, 132, normal fault that bounds the Pilion area seawards and 142,152)show strike-slip faulting. However, noneofthe fault strikesNW–SE. planes is aligned with the direction of the deep bathymetry or basement. In general, one plane strikes almost E–W and TheGulfofVolosandsouthernThessaly dips north, whilst the other strikes N–S and dips west. The orientation of the E–W-striking plane is well determined Most earthquakes in this region occurred either north of the because of the clear diVerence in polarities at stationslocated Gulf of Volos or on the western border of the Karditsa Basin on the mainland. For the strike-slip events, the mechanisms (Figs 7 and 8). We located no seismic activity that can be diVer only slightly from those computed for large earth- clearly related to the Larissa Basin or to the Pilion and its quakes in the North Aegean Trough (Fig.2) (Taymaz et al. edges. The clear normal faults that dip eastwards and bound 1991). theSEedgeofthePilionwereinactiveduringourexperiment. The southern cluster lies at the western border of the AroundtheKarditsaBasin,seismicactivityislocatedatthe Sporades Basin, just north of Skopelos, where the deepest westernedge,whereastrong(Ms7.0)earthquakeoccurredin basin is located. The bathymetry is 1000m but the basement 1954 and was associated with N–S extension (Papastamatiou is more than 10000m deep (Le Pichon et al. 1985). More & Mouyaris 1986). Most of this seismicity is restricted to the precisely we can observe two subclusters. The first is located Pinduschain,whosewesternsideisalsoquiteactive(Hatzfeld at the southern edge of the basin, with no clear shape, et al. 1995). The seismicity reveals no clear relation to the suggesting a single active fault. The second is located just NW–SE-strikingfaultsystemthatboundstheKarditsaBasin, northofthe islands ofSkiathos and Skopelos andcrosses the and we could not compute focal mechanisms because these NW–SE-striking faults inferred from the bathymetry (Lyberis earthquakeswere locatedoutsidethe network. 1984).Wecouldnotdeterminemechanismsforthefirstcluster North of the Gulf of Volos, the seismic activity is concen- becauseitislocatedoutsideournetwork,andtheearthquakes trated in two clusters. The first is clearly associated with the were not strong enough to be recorded by the permanent Nea Anchialos Fault system, which strikes E–W, dips south- stations.TheearthquakeslocatednorthofSkiathos(#119,121, wards and bounds the northern edge of the Almyros Basin. 125, 159, 396, 440) clearly show strike-slip motion with one This region experienced several strong earthquakes during planestrikingNE–SW,approximatelyparalleltothestrikeof historical time in 743 and 1773 according to Papazachos & the North Aegean Trough, and the other NW–SE, which Papazachou (1997), and in 1980 when a magnitude Ms 6.5 diVersbyabout30°fromthestrikesofnormalfaultsbounding event occurred. The foreshocks and aftershocks of the latter the Pilion to the east. This seismicity pattern continues west event are well aligned with the Nea Anchialos Fault and the towardstheGulfofVolos,butthestyleoffaultingprogressively focal mechanismindicatesaN–S-trendingextensionalongan changestonormalfaulting(#24,25,141,171,425,448)across E–W-striking fault (Papazachos et al. 1983). The distribution ©1999RAS,GJI137,891–908 896 D. Hatzfeld et al. Table1. of the microearthquakes confirms that the Nea Anchialos seismicity to any of those structures. Nevertheless, the Nea Fault continues eastwards across the Pilion as proposed by PagasaeFaultseemstobethemostplausiblebecausethedipof Caputo (1996). A N–S-trending section (Fig.9a) across the the structure fits the distribution of the earthquakes located at faultshows south-dippingactivitydown to10km. about5kmdepth(Fig.9b). The second cluster is located near the region of Velestino, TheNeaAnchialosandNeaPagasaefaultsareE–W-striking whereanearthquakeofmagnitude6.8andtwoothersofmagni- antithetic normal faults. The better-constrained focal mech- tudegreaterthan6.0occurredwithin12hrin1957(Papazachos anisms (#4, 209, 356), as well as the less well-constrained & Papazachou 1997). No ground rupture was observed, and solutions(#61,208,215,421)associatedwiththeNeaAnchialos there was no obvious evidence relating this earthquake to any Fault indicate E–W-striking normal faulting. We obtained a fault,eventhoughtheRigheoFaultcouldbeagoodcandidate similar pattern for the focal mechanisms associated with the (Caputo1990).Ourseismicitysplitsintotwoclustersthatalign Nea Pagasae Fault (#33, 37, 297, 383, 386, 389, 398). In approximatelyE–W.BecausetherearemanyfaultsstrikingE–W conclusion,itseemsclearthatthisareaisunderN–Sextension inthisareasuchastheVelestino,theRigheo,theVassilikaand along a set of E–W-striking parallel faults. It is worth noting theNeaPagasaefaults(Caputo1990),itisdiYculttorelateour thatafewevents,locatedtotheeast,exhibitaslightcomponent ©1999RAS,GJI137,891–908 Microseismicity around Volos (Greece) 897 Table1. (Continued.) of strike-slip motion, which is consistent with the events does not show any seismicity associated with this fault. Due recordedin southernPilion. to the impressive normal faults observed along Kallidromon andKamenaVourlaforseveraltensofkilometres(Philip1976; Lemeille 1977), this lack of seismicity can be interpreted as a LocridandnorthernEvia seismic quiescenceperiodbetween major earthquakes. One of the major goals of our experiment was to investigate Important seismicity is located around the Lamia Basin, the seismicity located south of the Gulf of Volos (Figs 10 the Renginion Basin and northern Evia. The microseismicity and 11). This region experienced very strong earthquakes in showsadiVusepatternthatcannotbedirectlyassociatedwith historical time, in 426 bc, in 1740 and more recently in 1894. anyspecificfaultsuchastheKamenaVourlaor Kallidromon This most recent event, known as the Atalanti-Martinon faults, but seismic activity unquestionably occurs as deep as earthquake, was composed of two shocks of magnitudes 6.5 15km.MinoractivityoccurredaroundtheAtalanti-Martinon and 6.7, a week apart. Remnant surface breaks that are still Fault.TheearthquakeslocatedbeneathnortheasternEviaare visibletodayshownormalfaultingwiththereactivationofthe unlikelytobeassociatedwithanyoftheknownsurfacefaults, N300°-striking fault (Ambraseys & Jackson 1990). However, because the western Kandili Fault dips westwards and the instrumentalseismicity(evenlocatedbytheregionalVOLNET easternEviaFaultdipseastwardsandthereforeawayfromthe seismological network operated by the University of Athens) seismic activity(Fig.9c). ©1999RAS,GJI137,891–908 898 D. Hatzfeld et al. Figure5. SeismicitymapofthenorthernAegeanseashowingthereliablylocatedearthquakeswithuncertaintiessmallerthan5kmandrecorded by more than eight stations. The major faults are shown with heavy and thin lines for the Quaternary and Pliocene structures, respectively (afterMercieretal.1976;Roberts&Jackson1991;Caputo&Pavlides1993). Figure6. MapshowingfocalmechanismscomputedforthenorthernAegean.Solidquadrantsincludecompressionalfirstmotion;openquadrants showdilatations.Blackquadrantsindicatecategory1mechanismswithtwoplaneswellconstrained;darkgreycategorytwomechanismswithone planewellconstrained;lightgreycategory3mechanisms.Wenotethatthedextralstrike-slipmotionalongtheNorthAegeanTroughprogressively transfersintopurenormalfaultingonE–W-strikingplanesandN–SextensionaroundtheGulfofVolos. ©1999RAS,GJI137,891–908 Microseismicity around Volos (Greece) 899 Figure7. SeismicitymapofthereliablylocatedearthquakesinThessalyandtheGulfofVolos.NoearthquakesarelocatedalongtheNW–SE- striking faults that bound the Pilion to the east and the Larissa Basin. The major faults are reported with the same convention as in Fig.4. VF:Velestino; RiF:Righeon;BV: Vassilika; NPF:Nea Pagasae;TF: Tyrnavos; NAF:Nea Anchialos; AF:Ambelia.Seismicity is associated with theNeaAnchialosFault,theVelestinoFaultsystemandtheLamiaBasin.Thelocationsofthecross-sectionsA–A∞andB–B∞arealsoshown(Fig.9). Figure8. Map of the focal mechanisms computed for Thessaly and the Gulf of Volos (symbols as in Fig.5). Note the transition from dextral strike-slipmotionaroundtheislandofSkiathostotheN–S-trendingpureextensionalongtheNeaAnchialosFault. ©1999RAS,GJI137,891–908 900 D. Hatzfeld et al. (a) The focal mechanisms show two distinct patterns. Beneath the Lamia Basin, west of the city of Lamia (#55, 57, 183, 265, 277) and close to the Kallidromon, the Kamena Vourla faults and the Renginion Basin (#226, 329, 341, 342), mainly normalfaultingalongE–W-strikingfaultsisobserved.However, in northern Evia focal mechanisms (e.g. #99, 254, 279, 407) indicatestrike-slipfaultingwithT-axestrendingapproximately N–S. We have found no evidence that the same occurs along the Atalanti-Martinon Fault (#180, 425). Therefore, although alltheT-axesareorientedapproximatelyN–S,paralleltothe regional extension (Mercier et al. 1989; Caputo & Pavlides 1993), the two diVerent types of focal mechanisms (normal and strike-slip) suggest that individual blocks are limited by inherited faults. DISCUSSION The pattern of microseismicity that we obtained from seven weeks of recording shows some common features and some diVerences compared to the instrumental seismicity map (b) provided by NEIS locations (Fig.1), the historical seismicity (Fig.2, Papazachos & Papazachou 1997) and the most important faults. Onallmaps,weseeseismicactivityalongtheNorthAegean Trough, around the Gulf of Volos and west of the Karditsa Basin. In some places (e.g. the North Aegean Trough or the Nea Anchialos Fault) the seismicity is associated with known active(orveryrecent)faults.Insomeareas(e.g.Velestino-Nea Pagasae system) activity is notclearly associated with specific faults,andinonecase(theLamiaBasin)ourpreciselylocated earthquakescannotbeassociatedwithanymappedfault.This observationimpliesthatbrittledeformationisnotconfinedto important individual surface faults, but is distributed over broad areasor associated withhidden faults. On the other hand, some important tectonic features are not related to any seismic activity. This is especially true for most of the large NW–SE-striking faults such as that to the east of Pilio, in Locrid, or those bounding the Karditsa and (c) Larisa basins where Pliocene activity has been documented (Caputo1990). We will describe in more detail a few regions of particular interest. TheeasternPilion We didnot locate any earthquake along the NW–SE-striking normal faults that bound to the east the Pilion region and to thewesttheSporadesBasin(Fig.7).Also,wedidnotobserve any significant seismic activity along the eastern coast of Evia(Fig.10).Thisisalsotrueforinstrumentalandhistorical seismicity. Therefore, these faults seem seismically inactive at the present time, even though they were important active featuresduringthePliocene.Accordingtomostoftheproposed models of the geodynamic evolution of the Northern Aegean, Figure9. Cross-sectionsacross(a)theAlmyrosBasin,suggestingthat the Sporades Basin is an important extensional feature theNeaAnchialosFaultisactive, (b)theVassilika Basinand(c) the bounded to the west by an active fault (Taymaz et al. 1991; GulfofEvia,whichdonotshowaclearpatternofseismicityassociated Dinter&Royden1993;Jolivetetal.1994;Armijoetal.1996). withspecificfaults. However,noseismologicalevidenceofsuchaNW–SE-striking active normal fault is found in the historical seismicity or in ourdata. In contrast, microseismicity is located in areas that were inactiveoninstrumentalseismicitymaps(Fig.10).Inparticular, ©1999RAS,GJI137,891–908
Description: