Pseudotachylyte in the Monte Maggiore ophiolitic unit ( Alpine Corsica ) : a possible lateral extension of the Cima di Gratera intermediate-depth Wadati-Benioff paleo-seismic zone

This is anOp Abstract – At the northern end of the Cap Corse pe ninsula, several klippes of ultramafic rocks (peridotite and serpentinite), among which the Monte Maggiore klippe is the least serpentinized one, rest upon continental-crust derived rocks (Centuri gneisses) and basic or metasedimentary schists (Schistes Lustrés). The Monte Maggiore ophiolitic klippe shares several characteristics with the Cima di Gratera klippe located 30 km further south. First, the two units are composed of a lherzolitic peridotite. Second, they record the same succession of metamorphic events. Third, in the Cap Corse tectonic pile, the two units occupy the highest structural position. Several differences are also observed. First, mafic rocks are significantly less abundant in the Monte Maggiore unit, where they are restricted to dykes cross-cutting the peridotite, than in the Cima di Gratera unit, where they constitute an entire sub-unit. Second, pyroxenite layers are more common at Monte Maggiore than at Cima di Gratera. Despite these differences, the Monte Maggiore and Cima di Gratera klippes can be considered as possible lateral equivalents of a single ophiolitic unit having covered the entire Cap Corse before subsequent erosion. Pseudotachylyte of seismic origin is newly discovered in theMonteMaggiore klippe. The host rock is a cataclastic serpentinized peridotite affected by a cataclastic foliation that is either flat-lying or steeply dipping. Pseudotachylyte fault veins are parallel to the host rock cataclastic foliation. The small lateral extension and the small thickness of fault veins along with frequent cross-cutting relationships suggest that the exposed pseudotachylyte most likely results from numerous small magnitude seismic events such as swarms or aftershocks rather than from large magnitude shocks. All these characteristics are also observed at the Cima di Gratera klippe where they are interpreted as the testimonies of a fossil intermediate-depth Wadati-Benioff zone at the time of subduction of the Ligurian Tethys oceanic lithosphere. Mineral assemblages that could constrain the depth of formation of the pseudotachylyte lack in the Monte Maggiore area. Despite this uncertainty, and given the similarities with the Cima di Gratera occurrences, the pseudotachylyte veins newly discovered at Monte Maggiore are tentatively related to the seismic activity linked with the subduction of the Piemonte-Ligurian oceanic lithosphere in Eocene times. This interpretation suggests that the fossil Wadati-Benioff zone could be traced further south in Alpine Corsica and further north in the Piemontese zone of the western Alps.


Introduction
Subduction zone seismicity consists of shallow earthquakes (hypocenters shallower than 60 km), intermediatedepth earthquakes (hypocenters between 60 and 300 km), and deep-focus earthquakes (hypocenters deeper than 300 km).Large magnitude (> 8) events of the first category typically nucleate and propagate between the subducting plate and the overriding plate.Their hypocenters therefore delineate the plate interface.Intermediate-depth and deep-focus earthquakes nucleate in the subducting slab, either in the crust or in the underlying mantle.Their hypocenters are aligned along what is classically referred to as the Wadati-Benioff seismic zone.In most subduction zones, precise hypocentral locations allow to further divide the Wadati-Benioff seismic zone into two subzones (Brudzinski et al., 2007).The separation between the two sub-zones is estimated between 8 and 30 km, and appears to be a function of the age of the subducting plate.The upper sub-zone is located in the crust and/or in the uppermost part of the underlying mantle, while the lower sub-zone lies in the mantle (Igarashi et al., 2001;Preston et al., 2003;Kita et al., 2006;Abers et al., 2013;Nakajima et al., 2013).
Little is known about the exact mechanisms which control seismicity at intermediate depths.First, do intermediate-depth ruptures propagate along "standard" fault surfaces like in shallower depths or in volumes of several tens or hundreds of meters in thickness?Second, do these earthquakes reactivate already existing faults (for instance faults formed at the midoceanic ridge or at the trench outer wall in response to plate bending), or do they nucleate along newly formed faults [see contradictory views in Jiao et al. (2000) and Warren et al. (2007)]?Third, what is the mechanism allowing intermediatedepth event to occur?Indeed, given the high confining pressures at such depths, potential faults should be stable, yet earthquakes occur.Two main mechanisms are currently under consideration to account for this paradox (Frohlich, 2006;Houston, 2015).The first mechanism is based on a fluid pressure increase at depth along potential fault surfaces, increase that could in turn bring faults to failure by reduction of the normal stress component acting on the faults.In this mechanism, dehydration reactions of hydrated minerals, typically serpentine, are frequently called for to account for the source of fluids (e.g., Peacock, 2001;Hacker et al., 2003).One example of such a mechanism frozen in the geological record is provided by Angiboust et al. (2012) in the Western Alps Monviso ophiolite.The second mechanism is referred to as thermal instability or as self-localizing (or spontaneous) thermal runaway (Braeck and Podladchikov, 2007;Kelemen and Hirth, 2007).The basic idea underlying this mechanism is that the shear strength of incipient ductile shear zones can drop suddenly, leading to shear heating and localized melting, hence resulting in a seismic rupture.Geological evidence for this mechanism should therefore require a close spatial association (that is, juxtaposition) of mylonite and pseudotachylyte along with evidence showing that the two types of rocks formed simultaneously.An example of such a spatial and temporal association in the geological record is provided by John et al. (2009).Besides, seismological data further suggest that the thermal runaway mechanism may account for the nucleation of intermediate-depth earthquakes in some subduction zones (Prieto et al., 2013).Conversely, Scambelluri et al. (2017) consider that the seismic ruptures frozen in the Western Alps (Lanzo Massif ophiolite were not caused by either of the two mechanisms mentioned above, but to "a release of differential stresses accumulated in strong dry metastable rocks".A similar interpretation was proposed by Menant et al. (2018) in their study of pseudotachylyte preserved in the Dent Blanche Valpelline continental unit.In other words, for these authors, an increase of the differential stress may allow a rupture, even if the normal stress is high.Albeit not conclusive, answers to these questions can also be looked for in the geological record, where evidence of intermediate-depth seismic ruptures can be preserved.
Pseudotachylyte veins exposed in the Cima di Gratera ophiolitic unit, Cap Corse peninsula (Alpine Corsica, France), are of seismic origin and a part of them was generated under blueschist to eclogite facies metamorphic conditions (Austrheim and Andersen, 2004;Andersen and Austrheim, 2006;Andersen et al., 2008Andersen et al., , 2014;;Deseta et al., 2014a, b, Magott et al., 2016, 2017).These veins were most likely formed in Late Cretaceous or Paleogene times during earthquakes in the Wadati-Benioff seismic zone of the Ligurian Tethys oceanic lithosphere subducting beneath a continent or an island arc.
The aim of this contribution is to report a new finding of pseudotachylyte from the northern end of the Cap Corse peninsula, in the Monte Maggiore ultramafic unit, and to discuss correlations between this occurrence and pseudotachylytes reported from the Cima di Gratera ophiolitic unit located 30 km south.These new findings suggest that the extension of the paleo-seismic Wadati-Benioff zone could be larger than initially thought (a few tens of kilometers instead of a few kilometers).They allow a discussion of the geodynamical significance of the Corsican pseudotachylytes within the general framework of the Alpine orogeny and the detailed setting of a Wadati-Benioff seismic zone of a subducting Tethysian oceanic lithosphere in Mesozoic to Cenozoic times.
2 Geological setting of Alpine Corsica
Ophiolitic thrust sheets of domain (3) are constituted by peridotite, serpentinite, gabbro and basalt and are regarded as lithospheric remnants of the Jurassic Ligurian Tethys (Piemonte-Ligurian) oceanic basin.Radiometric dating of the oceanic gabbros and plagiogranites yielded Middle to Late Jurassic ages between 181 and 152 Ma (Beccaluva et al., 1981;Ohnenstetter et al., 1981;Rossi et al., 2002;Rampone et al., 2009;Li et al., 2015).The lack of dyke complex, the scarcity of magmatic rocks and the discontinuous distribution of gabbro bodies indicate that the spreading ridge of the Piemonte-Ligurian basin was of slow to very slow type (Lagabrielle and Lemoine, 1997;Piccardo, 2008).

Models for the Alpine evolution
The imbrication of continent-derived thrust sheets (domain 2) with ophiolitic units (domain 3) is classically interpreted as the result of an eastward-dipping Cretaceous to Paleogene subduction of the Piemonte-Ligurian oceanic basin and a part of the stretched European margin beneath the Apulia continental lithosphere followed by collision between Europe and Apulia in Eocene times (Mattauer and Proust, 1976;Mattauer et al., 1977Mattauer et al., , 1981;;Warburton, 1986).Imbricated thrust sheets from domains (2) and (3) can be regarded as a suture between the two continental entities.The classical Alpine evolutionary model was further complicated by taking into account the Apennine orogeny (e.g., Durand-Delga and Rossi, 2002).The east-dipping Cretaceous subduction was followed in Paleocene to Eocene times by a west-dipping subduction of the oceanic lithosphere of a back-arc basin formed further east (Jolivet et al., 1998;Lacombe and Jolivet, 2005;Molli, 2008;Molli and Malavieille, 2010;Agard and Vitale-Brovarone, 2013;Vitale-Brovarone and Herwartz, 2013).
3 Geology of the study area and regional correlation
The Monte Maggiore unit consists of a series of ophiolitic klippes (Lahondère and Lahondère, 1988;Jolivet et al., 1991;Lahondère, 1992), among which the westernmost one is referred to as the Monte Maggiore klippe (Fig. 1).These klippes, which are made of variously serpentinized peridotites with scarce gabbroic rocks, rest upon continental crust-derived gneisses or upon oceanic-affinity meta-basalts (also called prasinites) and meta-sedimentary rocks.
Intact (i.e., not serpentinized) peridotites are preserved in most of the Monte Maggiore klippe while, in the other klippes located further east, the peridotite is thoroughly serpentinized.The peridotite is a clinopyroxene-poor spinel lherzolite.The typical mineralogical composition consists of olivine, orthopyroxene, clinopyroxene, spinel and plagioclase (Jackson and Ohnenstetter, 1981;Rampone et al., 2008;Piccardo and Guarnieri, 2010).Planar layers of pyroxenite are locally observed in the Monte Maggiore klippe, as well as mafic rocks which are limited to small size dykes and pods of gabbros (troctolites to Fe-rich gabbros), Fe-rich diorites, dolerites and albitites sporadically intruded in the mantle rocks (Jackson and Ohnenstetter, 1981;Rampone et al., 2008;Piccardo and Guarnieri, 2010).These intrusive and extrusive rocks possess a MORB-type geochemical signature (Rampone et al., 2008;Piccardo and Guarnieri, 2010).Absolute datings of peridotite and gabbroic dykes with various methods provided Late Jurassic ages (181 to 155 Ma) for MORB melt percolation (Beccaluva et al., 1981;Ohnenstetter et al., 1981;Rampone et al., 2009;Piccardo and Guarnieri, 2010).Jackson and Ohnenstetter (1981) report that the Monte Maggiore peridotite suffered from three metamorphic imprints (see also Ohnenstetter et al., 1976).An oldest greenschist to amphibolite facies condition event (1), likely Jurassic in age, is tentatively related to hydrothermal fluid flow at or near the mid-oceanic ridge.This early event is overprinted by a HP/LT event (2) which is attested, in plagioclase-bearing peridotite, by the presence of pure jadeite (Jackson and Ohnenstetter, 1981).In gabbroic intrusive rocks, Debret (2013) further describes mineral assemblages typical of blueschist facies conditions, namely jadeite, paragonite, zoisite and chlorite.This second event is tentatively related to the subduction, in  Lahondère andLahondère 1988, 1992).SA is Sant'Antonino klippe.B. Geological sketch map of the Monte Maggiore klippe with pseudotachylyte localities.C. A-A' cross-section (see location on B).
Cretaceous to Paleogene times, of the Piemonte-Ligurian oceanic lithosphere.The youngest greenschist facies condition event (3), overprinting event (2), is possibly related to syn-to post-collision deformation, but its age is poorly constrained.
The Monte Maggiore peridotite shows a widespread foliation striking N120 to N160°E and dipping moderately to strongly westward to southwestward.According to Jackson and Ohnenstetter (1981), the foliation is a mineral flattening surface which results from a high temperature (> 1100 °C) solid-state plastic flow.It bears a mineral and stretching lineation whose rake is close to zero.
Near the basal contact of the Monte Maggiore klippe, the peridotite is variably serpentinized, but the original granoblastic texture is still recognizable.Deformation consists in fractures which are locally abundant, with some scattered foliated shear zones whose thickness does not exceed a few meters.In the foliated shear zones, the foliation is deflected by shear surfaces.The S/C-like composite fabric indicates a component of reverse displacement.A thin band of very finegrained chlorite-epidote-rich ultramylonites separates the serpentinized peridotite from the underlying kinzigitic gneisses of the Centuri gneiss continental unit.The presence of epidote, chlorite and albite suggests that the chloritic schists are mylonitic serpentinites which suffered from fluid-assisted alteration during nappe emplacement.

The Cima di Gratera ophiolitic klippe
Unlike the Monte Maggiore unit, the Cima di Gratera ophiolitic unit, which lies as a klippe over continental crustderived rocks, is a tectonic superposition of two units: a lower ultramafic unit and an upper gabbro unit.The two units are separated by a composite brittle/ductile shear zone referred to as f 2 and which structural analysis can be found in Magott et al. (2017).

The lower ultramafic unit
The lower ultramafic unit consists of decameter to hectometer scale elliptical lenses of intact peridotite surrounded by moderately to strongly serpentinized peridotite.In the lowermost part, several slices of strongly foliated gabbro or of metasedimentary rocks are interpreted as the result of tectonic incorporation of the subjacent units during nappe emplacement.Metamorphic conditions during this tectonic incorporation were at least those of the greenschist facies.Higher conditions are suggested by bluish basic schist lenses, but the pervasive greenschist facies retrogression affecting the slices makes a detailed study difficult.Near the f 1 basal tectonic contact, the lower part of the unit consists of foliated serpentinites whose foliation is severely folded or sheared.This intense basal deformation, which is interpreted as a consequence of the emplacement of the nappe over its substratum, is more intense than the Monte Maggiore area.Serpentinite predominates in the lower part of the ultramafic unit and the degree of serpentinization decreases upwards from f 1 and towards f 2 .Pyroxenite layers and gabbroic intrusions are significantly scarcer than in the Monte Maggiore area.The Cima di Gratera peridotite is lherzolitic in composition, and is constituted by olivine, diopside, enstatite and minor plagio-clase, Cr-spinel and magnetite (Deseta et al., 2014a, b).The geochemical characteristics of the Cima di Gratera rocks are much less known than their counterparts in the northern study area.The succession of the three metamorphic events (greenschist facies condition event !blueschist facies condition event !greenschist facies condition event) described in the Monte Maggiore area is also reported from the Cima di Gratera ultramafic unit (Deseta et al., 2014a, b;Magott et al., 2016Magott et al., , 2017)).

The upper mafic unit
The mafic unit is predominantly composed of an equant metagabbro.Primary minerals are plagioclase, diopside, minor olivine and rare ilmenite.Alteration of plagioclase into sericite and of olivine into serpentine, iddingsite and magnetite is common.The texture often changes from, microgabbro to coarse-grained gabbro and to pegmatitic gabbro.Rare dolerite dykes cross-cut the gabbro.The basal part of the mafic unit consists of, a mylonitic metagabbro characterized by a conspicuous flat-lying to gently dipping foliation and a weakly marked lineation trending N120°E.The thickness of the mylonitic basal part is between 20 cm and 30 m.As in the ultramafic unit, the succession of three metamorphic events (greenschist facies condition event 1, blueschist facies condition event 2, greenschist facies condition event 3) described in the Monte Maggiore area is also recognized in the mafic unit (Deseta et al., 2014a, b;Magott et al., 2016Magott et al., , 2017)).

Correlation with the Cima di Gratera ophiolitic klippe
The Monte Maggiore ophiolitic unit shares several characteristics with the Cima di Gratera unit.First, the two units are composed of a similar initial rock type, namely a lherzolitic peridotite.Second, the two units underwent the same succession of three metamorphic events.Third, in the Cap Corse tectonic stacking, the two units occupy the highest structural position (Lahondère andLahondère, 1988, 1992;Lahondère, 1992).
Several differences are also observed.First, mafic rocks are significantly less abundant in the Monte Maggiore unit, where they are restricted to dykes cross-cutting the peridotite, than in the Cima di Gratera unit where they constitute an entire sub-unit (with rare dykes in the underlying ultramafic unit).The lack of mafic rocks in the Monte Maggiore unit can be explained in two ways.It can result from more advanced erosion in the north than in the south, or it can also be due to the sporadic occurrence of mafic plutons in slow-spreading ridges.Second, pyroxenite layers, common in the Monte Maggiore unit, are scarce in the Cima di Gratera unit.
Despite the differences, the Monte Maggiore unit and the Cima di Gratera unit can be considered as possible lateral equivalents of a single ophiolitic unit having covered the entire Cap Corse before being eroded except at the two ends of the peninsula.This tentative correlation between the two scattered units will be a working hypothesis for the rest of the paper.

Pseudotachylyte and ultracataclasite in the Monte Maggiore klippe
Peridotite-hosted pseudotachylyte veins in the Monte Maggiore klippe, initially reported by Magott (2016), are exposed at two localities close to the 359 m summit and, at a third locality close to another summit at 323 m (Fig. 1).

Host peridotite cataclastic foliation
In addition to being moderately to strongly serpentinized, the peridotite hosting pseudotachylyte and ultracataclasite veins is foliated (Fig. 2).The foliation is cataclastic and overprints the primary foliation described by Jackson and Ohnenstetter (1981).It is either flat-lying to gently dipping eastwards, or steeply dipping eastwards (Fig. 2).At locality 1, the flat-lying to gently dipping foliation crosscuts the steeply dipping one (Fig. 3), suggesting it is younger.The deflection of the steeply dipping foliation by the flat-lying one suggests a top-to-the-W sense of shear (Figs.3A and 3B).Thin sections show that the cataclastic foliation primarily consists in fractures crossing primary minerals of the peridotite, and along which serpentinization is developed.Offset minerals indicate that some of the fractures are actually faults.Deflection of a former foliation by a younger one suggests a top-to-the-E shear sense (Fig. 4), at variance with the top-to-the-W shear sense deduced from outcrop-scale deflections (Fig. 3).

Pseudotachylyte veins
Pseudotachylyte veins are distributed in the three outcrops, but their density increases upwards from the lowest parts of each exposure.A lot of minor faults truncate most veins.Despite this late brittle deformation, fault veins and injection veins can be identified (Fig. 5).Injection veins are rare and their length never exceeds 1 cm.Fault vein thickness varies between 1 and 5 mm.Their lateral extension cannot be estimated, due to exposure limitation or truncation by late faults.The largest visible extension is about 1 m.Fault veins are either isolated or form imbricated networks.Based on their attitudes, fault veins can be sorted into two groups: steeply dipping veins and flat-lying to gently dipping veins (Fig. 6).Steeply dipping veins predominate, where the cataclastic foliation dips steeply, whereas flat-lying veins or vein networks are found where the cataclastic foliation is flat-lying.Due to the lack of cross-cutting relationships, no relative chronology can be established between the two groups of veins.Conversely, within each group, cross-cutting relationships indicate that veins formed during several (i.e., at least two) seismic events.
Under the optical microscope, the light to dark brown matrix of the pseudotachylyte veins is cryptocrystalline and, in some instances, is crossed by a network of polygonal fractures reminiscent of devitrification textures (Fig. 7).Clasts are rare, well-rounded, and can show embayments.Most of them are very small (2 to 1 mm), but some can be up to 1 mm long.The nature of the clasts is varied: olivine, clinopyroxene and, to a lesser extent, pseudotachylyte.Acicular microlites are observed in the otherwise cryptocrystalline matrix.Like in Cima di Gratera pseudotachylyte veins, the largest (between 20 and 80 mm long) and most numerous microlites consist of clinopyroxene while the smallest (< 3 mm) and least abundant consist of olivine.At variance with the Cima di Gratera occurrence, orthopyroxene microlites were not observed in the Monte Maggiore veins.
The chemical composition of pseudotachylyte matrix and microlites was investigated by microprobe (Tab.1).Clinopyroxene microlites show augite to diopside compositions.Their Fe content is slightly lower than in the host-rock clinopyroxenes.Minor element contents (namely Cr 2 O 3 and NiO) of clinopyroxene microlites are similar to those of host-rock clinopyroxenes.Because of their small size, microprobe analysis of the olivine microlites is to be taken with caution, since the matrix surrounding the microlites was likely partly The results summarized in Table 1 further permit a comparison between the chemical composition of the Maggiore pseudotachylyte and that from the Cima di Gratera (Deseta et al., 2014a, b).The above mentioned Mg number (85.3) is similar to that of the olivine microlites (84.98) of the Cima di Gratera occurrences.Concerning clinopyroxene, the Ca content of the Monte Maggiore microlites (11.73 to 24.81% CaO, with most values around 23%) is higher than that of their Cima di Gratera counterpart (about 11% CaO).Conversely, the Mg content of the Cima di Gratera microlites (27.37 to 31.67%Mg0) is higher than that of their Monte Maggiore counterparts (17.35 to 26.97%, with most values around 18%).The same observation holds for Al content (2.36 to 6.5% Al 2 O 3 at Cima di Gratera vs. 0.93 to 3.5% at Monte Maggiore).For both occurrences, the FeO content is quite varied, but the values remain similar (3.36 to 8.5% FeO for Cima di Gratera, 2.32 to 7.03% for Monte Maggiore).Lastly, for the two occurrences, the vein matrix shows a composition close to that of olivine, with significant contents in Al 2 O 3 and CaO likely reflecting the melting of aluminous-rich minerals in the host peridotite, namely spinel and plagioclase.Together, these analyses suggest that the chemical composition of pseudotachylyte veins from the Cima di Gratera and Monte Maggiore localities are similar.

Ultracataclasite veins
Ultracataclasite veins are observed at locality 1, where the peridotite foliation is flat-lying or gently dipping.They look like the pseudotachylyte veins (same dark green color, same flat-lying attitude), but are thicker (from 5 mm to 2 cm), do not show the glassy aspect of the pseudotachylyte and lack injection veins.They are flat-lying or gently dipping, like the cataclastic foliation of the host rock.
In thin sections (Fig. 8), ultracataclasite shows angular clasts of pyroxene, olivine, feldspar and variably serpentinized peridotite.The smallest clasts are beyond the resolution of the optical microscope, while the largest can be up to 5 mm long.In addition to host rock-derived clasts, fragments of pseudotachylyte are abundant.They typically display elliptical shapes whose largest dimension can reach 2 mm.Pseudotachylyte remnants, still attached to the wall rock, are also present along the vein boundaries.These observations suggest that ultracataclasite "veins" or layers are in fact former pseudotachylyte veins that were subjected to brittle shear reactivation.The incorporation of the host serpentinized peridotite suggests that some vein thickening occurred during reactivation.Because of the lack of any indicator, the kinematics of the brittle reactivation of the pseudotachylyte fault veins cannot be determined.No cataclastic reactivation could be observed along steeply dipping pseudotachylyte veins.

Depth of formation of the Monte Maggiore pseudotachylytes
Like the Cima di Gratera occurrences, the Monte Maggiore peridotite-hosted pseudotachylyte veins lack mineral assemblages that could provide an estimate of the pressure (that is, the depth) of formation.In the Cima di Gratera case, a depth estimate can be inferred from omphacite microlites in gabbrohosted veins, which were most likely formed contemporaneously with the peridotite-hosted veins.The preservation of omphacite indicates a pressure of 1.8-2.6MPa, that is, a depth of formation between 60 and 90 km (Deseta et al., 2014a;Magott et al., 2017).In the Monte Maggiore unit, the gabbro dykes do not contain any pseudotachylyte veins.They therefore do not provide any constraint regarding the depth of fossilized seismicity.Earthquakes could have occurred at depth in the subducting slab, like for the Cima di Gratera occurrences, but also at shallow depths at the ridge during oceanic accretion.The only observations that can put some constraints on the depth of formation of the Monte Maggiore paleo-earthquakes consist in antigorite veins cross-cutting pseudotachylyte veins (Fig. 9).Since antigorite is a polymorph that forms only at high temperature, this cross-cutting relationship rules out formation of pseudotachylyte during the last stages of exhumation or after exhumation.Additional petrographical investigations are needed to specify whether the Monte Maggiore pseudotachylyte was formed at the midoceanic ridge or in the Wadati-Benioff zone of the subducting slab.

Chronology and kinematics associated with pseudotachylyte-forming and cataclasite-forming events and comparison with observations from the Cima di Gratera pseudotachylyte
In the Monte Maggiore klippe, pseudotachylyte fault veins are hosted in a cataclastic peridotite and are flat-lying or steeply dipping.They are parallel to a cataclastic foliation developed in the host peridotite.The steeply dipping cataclastic foliation is cross-cut by the flat-lying cataclastic foliation, showing that it is older and suggesting that steeply dipping pseudotachylyte fault veins could likewise be older that the flat-lying ones.The deflection of the steeply dipping foliation suggests that the sense of shear associated with the flat-lying cataclastic foliation is top-to-the-W.Within each of the two groups of pseudotachylyte veins (i.e., flat-lying vs. steeply dipping), cross-cutting relationships indicate that fault veins formed during several (at least two) seismic events, although the exact number of events cannot be estimated.These field observations are similar to those concerning the Cima di Gratera peridotite-hosted fault veins (Magott et al., 2016(Magott et al., , 2017)), with one difference: while at Cima di Gratera, the chronology between steeply dipping and flat-lying cataclastic foliations could not be determined, it can be ascertained in the Monte Maggiore area (Figs. 2 and 3).
Thin-section scale observations relevant to chronology and kinematics of deformation can be summarized as follows: n=42 Locality 1 Locality 2 Fig. 6.Lower-hemisphere equal-area projections of poles to pseudotachylyte fault veins from localities 1 (black circles) and 2 (red triangles).
due to the lack of shear sense criteria, the kinematics of the seismic slip that led to the formation of pseudotachylyte veins remains unknown in the study area, while it is top-tothe-W in the Cima di Gratera area (Magott et al., 2016); some flat-lying pseudotachylyte veins were reactivated in a brittle manner and were changed into ultracataclasites.
Because of the lack of formation of frictional melt associated with this late reactivation, it is not possible to determine whether the brittle event was seismic or not; the kinematics of the formation of the flat-lying cataclastic foliation in thin section (top-to-the-E, Fig. 4) is opposite to that deduced from outcrop-scale observations (top-to-the-W, Fig. 3).
Unlike for the Cima di Gratera top-to-the-W shear sense (Magott et al., 2016), the kinematics of the seismic faulting that led to the formation of the Monte Maggiore pseudotachylyte veins is undetermined.Conversely, top-to-the-E shear senses are observed in the Monte Maggiore cataclastic reworking of the pseudotachylyte veins.Regional data (Faure and Malavieille, 1981;Mattauer et al., 1981;Fournier et al., 1991;Jolivet et al., 1991;Daniel et al., 1996) as well as observations from the Cima di Gratera (Ferré et al., 2016;Magott et al., 2017) show that: both top-to-the-Wand top-to-the-E shear senses are preserved in ductilely deformed rocks from Alpine Corsica and; top-to-the-E shear deformation post-dates the top-to-the-W one.The top-to-the-E brittle deformation preserved in the Monte Maggiore cataclastic peridotite could be related to this late deformation episode.However, the scarcity of samples on which shear sense criteria can be ascertained and the restricted spatial distribution of the deformed rocks prevents further discussion of this deformation.

Correlation between the Cima di Gratera and the Monte Maggiore pseudotachylyte occurrences
The Monte Maggiore pseudotachylyte occurrence is reminiscent of that from the Cima di Gratera.In the two areas, the rock hosting the veins is a cataclastic peridotite.Both steeply dipping and flat-lying (to gently dipping) veins are present.At the outcrop scale, the overall aspect of the veins is complex, due to anastomosed vein networks and to frequent offsetting of veins by minor faults.A ultracataclastic reworking of the flat-lying veins, with a top-tothe-E shear sense, is possibly preceded by a top-to-the-W cataclastic shear (foliation deflection), but relative chronology between the two events is lacking.The chemical composition of pseudotachylyte vein matrix and microlites in the Monte Maggiore area (this study) is quite similar to  that of their counterparts in the Cima di Gratera area (Deseta et al., 2014a, b).Further comparison between the two areas is hindered by the limited size of exposures in the Monte Maggiore area and by the uncertainty, in this last area, regarding the setting (midoceanic ridge or subducting slab) of earthquake hypocenters.Despite these two limits, it is however plausible that the Monte Maggiore occurrence could be the lateral equivalent of the lowest part of the pseudotachylyte-bearing ultramafic unit at the Cima di Gratera (Fig. 10), the possibly above-lying pseudotachylyte-bearing mafic rocks, if ever present, having been eroded.More specifically, in their study of the Cima di Gratera unit, Andersen et al. (2014) report an 80 cm thick pseudotachylyte vein and suggest that this vein is the result of a magnitude 7 or 8 event.The area of the rupture surface of such a large event is typically several hundreds to several thousands of square kilometers.Hence, the lateral extension (length) of such a rupture surface is between several tens and a few hundreds of kilometers (Strasser et al., 2010).The scars of such a large event, whatever the main rupture surface or the (numerous) small surfaces corresponding to the aftershocks, should logically be traced over large distances.It is not unrealistic to consider that the small veins exposed in the Monte Maggiore unit are aftershocks of one or several large ruptures exposed in the Cima di Gratera unit.At a more regional scale, lateral equivalents of this fossil seismic zone should be looked for further south in Corsica as well as further north in the Western Alps.Since the timing of the first (oldest) rotation overlaps that of the high-pressure metamorphism, there is an uncertainty regarding the amount of correction that must be applied to get the position of the slab at the epoch of subduction.Given the fact that the proposed reconstruction is drawn for the situation 35 Ma ago (approximate age of the peak high-pressure metamorphism) and by assuming that the rotation rate is constant with time, the amount of rotation experienced by the Corsica-Sardinia block is about 34°.

Conclusion
The Monte Maggiore unit, consisting in a series of klippes composed of ultramafic rocks (peridotite and serpentinite), tectonically rests upon continental crust-derived as well as oceanic crust-derived units.Its structural position as well as its petrological composition suggest that it is similar to the Cima di Gratera unit located 30 km further south.Pseudotachylyte veins present in the highest parts of the Monte Maggiore klippe display several similarities with veins reported from the ultramafic rocks of the Cima di Gratera unit in the southern part of the Cap Corse peninsula: the peridotite hosting the pseudotachylyte veins is cataclastic; both steeply dipping and flat-lying veins are exposed, although no relative chronology can be determined at Cima di Gratera; the large number of veins cross-cutting each other indicates a large number of seismic events.Moreover, the small lateral extension and the small thickness of fault veins suggest that the pseudotachylyte most likely results from numerous small magnitude seismic events such as swarms or aftershocks rather than from large magnitude shocks.
Conversely, the following points are at variance with what is observed at the Cima di Gratera area: due to the lack of high-pressure mineral assemblages in Monte Maggiore gabbros, an ambiguity regarding the depth and therefore the setting of pseudotachylyte formation remains there: Were veins formed at or near the mid-oceanic ridge or at depth along the Wadati-Benioff zone of the subducting Piemonte-Ligurian oceanic lithosphere?co-seismic (i.e., pseudotachylyte-associated) top-to-the-W sense of shear is ascertained at Cima di Gratera but not at Monte Maggiore; subsequent cataclastic reworking of pseudotachylyte is observed at Monte Maggiore but not at Cima di Gratera.
Despite these differences or uncertainties, the two pseudotachylyte occurrences hosted in mafic or ultramafic rocks from similar ophiolitic units in Cape Corse are possibly lateral equivalents.If so, they may represent the remnants of a dismembered Wadati-Benioff seismic zone, which was formed during the Late Cretaceous to Paleogene subduction of the Ligurian Tethys oceanic lithosphere.(Hasegawa et al., 2007) are given for comparison (see Magott et al. [2016] for further details).

Fig. 1 .
Fig. 1. A. Structural sketch map of Cape Corse peninsula showing the location of Monte Maggiore and Cima di Gratera ophiolitic units (modified afterLahondère and Lahondère 1988, 1992).SA is Sant'Antonino klippe.B. Geological sketch map of the Monte Maggiore klippe with pseudotachylyte localities.C. A-A' cross-section (see location on B).

Fig. 3 .
Fig. 3. Close views of the cataclastic foliations at locality 1. A. Steeply dipping cataclastic foliation deflected by the flat-lying cataclastic foliation.Deflection indicates a top-to-the-W sense of shear.B. Steeply dipping cataclastic foliation truncated by the flat-lying cataclastic foliation.

Fig. 4 .
Fig. 4. Scanner image of a thin section showing a cataclastic peridotite crossed by a pseudotachylyte fault vein (pst) and by a cataclasite layer (cat) formed at the expense of a pre-existing pseudotachylyte fault vein.

Fig. 5 .
Fig. 5. Outcrop-scale aspect of pseudotachylyte (pst) fault veins crossing serpentinized peridotite (pictures A to D from locality 1, E from locality 3). A. Isolated flat-lying fault vein.B. Gently to moderately dipping network of fault veins.C. Steeply dipping fault veins (viewed from above).D. Steeply dipping fault veins (side view).E. Hand sample polished section of a serpentinized peridotite showing a fault vein (fv) and injection veins (iv).

Fig. 7 .
Fig. 7. Photomicrographs of pseudotachylyte veins.A. Injection vein showing zonation parallel to boundaries with flow banding (outlined by aligned clasts) and with chilled margins (locality 1).The darker outer sides correspond to chilled margins.Note the presence of pseudotachylyte clasts indicating a polyphase seismic activity.B. Well-rounded clinopyroxene clast (cpx) embedded in a fault vein (locality 1).C. Scanning electron microscope image of olivine and pyroxene microlites in a fault vein (locality 1).D. Flow fold frozen in an injection vein (locality 2).E. Cryptocrystalline matrix of a fault vein pseudotachylyte showing polygonal cracks interpreted as devitrification textures (locality 2).

Fig. 8 .
Fig. 8. Photomicrographs of cataclasite layers formed by cataclasis at the expense of pseudotachylyte veins (width of pictures is 2.5 mm). A. Clast of pseudotachylyte embedded in an ultracataclastic matrix.B. Remnant of pseudotachylyte preserved along the boundary with host serpentinized peridotite.

5. 4
Figures 11 and 12 depict a possible paleogeographic setting of the subduction zone in the vicinity of Corsica at the time of formation of the Monte Maggiore pseudotachylyte veins.This reconstruction is based on the following assumptions: the Monte Maggiore pseudotachylyte veins were not formed at the mid-oceanic ridge or at shallow depths in the trench, but in the subducting slab at intermediate depths (> 60 km depth), following the same scenario as the one proposed for the Cima di Gratera occurrences (Andersen et al., 2008, 2014; Deseta et al., 2014a, b; Magott et al., 2016, 2017); the timing of the peak of the high-pressure metamorphism (eclogite facies conditions) and hence that of the associated subduction are Late Eocene, namely 37.5∼34 Ma (Vitale-Brovarone and Herwartz, 2013); off Corsica, in Late Eocene times, the subducting slab was dipping eastwards or southeastwards (in present-day coordinates), to account for the top-to-the-W or top-tothe-NW (in present-day coordinates) sense of shear associated with blueschist facies conditions ductile deformation (Mattauer et al., 1981; Magott et al., 2017), in agreement with the reconstructions of Handy et al. (2010), Molli (2008), Molli and Malavieille (2010) and Marroni et al. (2017); based on the paleomagnetic constraints obtained by Advokaat et al. (2014), the Corsica-Sardinia crustal block suffered from a counterclockwise rotation of ∼45°in postearly Eocene to pre-Oligocene times (50∼30 Ma) in addition to the well-recognized counterclockwise rotation of ∼35°in early Miocene times (21.5∼16Ma).

Fig. 9 .
Fig. 9. Pseudotachylyte vein-antigorite vein relationship.A. Scanner image of a part of a thin section showing an antigorite vein (Ant vein) cross-cutting a pseudotachylyte fault vein (Pst).Also indicated is the point (þ B) where the Raman analysis was done.B. Results of Raman micro-spectroscopy with antigorite characteristic spectral signatures.

Fig. 12 .
Fig. 12. Schematic cross-section A-A' showing the subduction of the Piemonte-Ligurian oceanic lithosphere beneath AlKaPeCa microcontinent along with the tectonic incorporation of parts of the subducting slab to the base of the upper plate.MM: future Monte Maggiore tectonic unit.No vertical exaggeration.

Table 1 .
Results of microprobe analyses of Monte Maggiore pseudotachylyte veins and host peridotite.