Skip to main content

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

An updated reconstruction of basaltic crust emplacement in Tyrrhenian sea, Italy


Basaltic crust is present in the oceans and marginal seas. Oceanic accretion from inception to ending may be usefully recognized in small basin setting like the Tyrrhenian. Alternating episodes of strong and moderate extensional tectonics characterized the small Tyrrhenian opening. Hyperextension (drifting) of late-Miocene and latemost Pliocene age was followed by Pliocene and Late Quaternary moderate extension (rifting). Early hyperextension (~7.5–6.3 Ma) acted in the submerged margin of Hercynian Sardinia. Sardinia offshore, E-directed low-angle faults were accompanied by MORB-like volcanism of non linear shape in the shallow Vavilov plain - inherited segment of alpine-age orogen. Late hyperextension (~1.9–1.7 Ma) acted along the central N-S lineament of Vavilov plain, former metamorphic core complex. At the lineament northern side, E-dipping detachment faulting exposed serpentinized peridotite. At the other side, Vavilov volcano was faulted and its east flank tilted westwards. At the same time, volcanism with affinity to transitional MORB induced opening of Marsili basin. The drift episodes were characterized by absence or scarcity of volcanic activity on the conjugated emerged margins. The rift episodes (respectively ~5–1.9 Ma, and ~1/0.8 Ma-Recent) saw growth of major north-south trending volcanoes in bathyal area as intense volcanic activity developed on the continental margins.


Oceans are thought to originate following continental rupture. Oceanic crust with MORB affinity forms in oceans and marginal seas. Basaltic crust accretion from inception to ending may be investigated straightforwardly in small basins rather than in ocean. Two episodes of hyperextension and E-MORB volcanism characterized the Tyrrhenian intra-orogenic basin opening1,2. The small oceanic basins of Vavilov and Marsili are located in the central part of the sea (Fig. 1) overlying west-directed subduction of lithosphere belonging to Adria/Ionian microplate. In and around the bathyal area are present stretched remnants of orogenic accretion exhibiting Hercynian, Alpine and Apenninic age. Rifting of Hercynian Corsica-Sardinia and inherited orogen of Alpine age was initiated in early Oligocene3,4. Burdigalian-age spreading (~20–16 Ma) of Sardinia-Provence oceanic basin accompanied the counter-clockwise rotation of the adjacent continental blocks of hercynian and alpine age. The Tyrrhenian orogen was produced by SE-directed, flat-slab subduction of lithosphere located to the east of Corsica-Sardinia foreland5,6. Orogenic accretion was followed by rifting which was in turn supplanted by convergent tectonics reflecting inversion of subduction polarity3. The W-directed, steep-slab type of subduction was linked to E-verging Apenninic thrusting, back-arc opening and slab migration. The flat-slab subduction produced alpine double vergence3,5,6 (Fig. 2). Eastdipping front- and westdipping back-thrusts crop out on the western and eastern margins (NE Corsica and Calabrian arc), respectively. Geophysical investigations, deep drilling results of the Deep Sea Drilling Project (DSDP) Leg 42 and of the Ocean Drilling Program (ODP) Leg 107, and seafloor sampling indicate that Vavilov and Marsili bathyal plains are floored by basalts and exposed ultramafic rocks, and were affected by rapid subsidence4,6,7,8,9,10,11,12. Since the basins’ magnetic anomaly field (Fig. 3) shows significant intensity but does not have the linear symmetric patterns typical of the ocean floor, the intra-orogenic Tyrrhenian opening can not be recognized in a straightforward way on the basis of magnetic signature13,14. Thus, in spite of young age (< 8 Ma) the Tyrrhenian spreading process remains poorly documented. In order to contribute to the comprehension of such process we have examined the relationships between (i) extensional tectonics and volcanism in bathyal area, and between (ii) this volcanism and volcanism developed on the conjugated continental margins.

Figure 1

The Tyrrhenian Sea. Shaded relief image derived from bathymetric data with sun illumination from NE, 45° over the horizon and no vertical exaggeration (grid resolution 100 m). Mercator projection at 40° N. Bathymetry of the Tyrrhenian region was obtained by merging all the available multibeam48,49,50 and EMODnet gridded data ( The multibeam data were processed by the Kongsberg Neptune/Poseidon packages; spatial analysis and mapping were performed using the GMT51 and PLOTMAP52 packages. Coastline from different map sources at scale 1:100,000.0 published by Istituto Idrografico della Marina was digitized in geographical coordinates by using the software DIGMAP53 and were converted to the WGS84 geodetic datum by the program DATUM54. Filled red circles indicate the DSDP 373 and ODP 650 sites that penetrated basaltic crust of Late Miocene (L-M) and Latemost Pliocene (Lm-P) age in the Vavilov and Marsili plains (VP and MP, respectively). Such early oceanization episodes were followed by episodes characterized by the emplacement of corresponding homonymous large central volcanoes. Black arrows indicate the direction of the L-M and Lm-P hyperextension pulses trending E-W and NW-SE, respectively. Besides ODP-Site-650, volcanic manifestations of Lm-P age are found also offshore from Sardinia (ODP-Site-654), and on Palmarola island (see text). Mg = Magnaghi volcano.

Figure 2

The Alps-Tyrrhenian-Apennines system. Shaded relief image of central Mediterranean region (Mercator projection at 40° N; illumination from NE, 45° over the horizon; horizontal resolution 250 m; no vertical exaggeration). Data48,49,50 and methods51,52,53,54 as in Fig. 1. Arrows show the east- and west-directed subductions that are present beneath the Alps and Apennines, respectively. Past E-directed descent of European plate to the east of Corsica-Sardinia originated the double vergence of Tyrrhenian submerged orogen of Alpine age. Abbreviations: AA = Adriatic-Apennines (external zone of the Apennines); FT = Front-thrusts of NE Corsica showing crystalline-metamorphic nature and alpine-age; TA = Tyrrhenian-Apennines (internal zone of the Apennines); SBP = Sardinia Basin Provence margin (France); DF = East-dipping detachment fault separating front- and back-thrust zones of central Tyrrhenian inherited orogen; BT = Back-thrusts of Calabrian Arc showing crystalline-metamorphic nature; plus and minus signs = extensional (−) and compressional (+) tectonic modes that are present in the Tyrrhenian- and Adriatic-Apennines, respectively; stars = location of Norcia/Amatrice/Monti Sibillini area affected by the extensional earthquake sequence from August 16 to January 2017.

Figure 3

Magnetic anomalies of the Tyrrhenian region. Colour shaded relief map of the reduced to the pole aeromagnetic anomaly field of Italy. The image was obtained with software PLOTMAP52 from gridded data of magnetic data projected to the common flight altitude of 2500 m and referred to geomagnetic epoch 1979. Inset (a) depicts bathymetry data and N-S trending magnetic lineaments linked to the Vavilov and Marsili volcanoes and surroundings. The anomalies associated with deep-seated basaltic crust have low intensity (up to 200 nT11) and shapes which are almost rounded or poorly elongated (diffusional spreading linked to strong extension and low-angle faults; i.e., drill-sites DSDP 373 and ODP 650). By contrast, the magnetic patterns linked to the high-standing volcanoes exhibit high intensity (up to 1500 nT) and elongated, better-organized configuration (quasi-linear spreading associated to moderate extension and high-angle faults; i.e., ODP drill-sites 655 and 651).

Episodes of magma-poor hyperextension of initial oceanization

Late-Tortonian/Early-Messinian (~7.5 – ~6.3 Ma)

Eastwards from the Sardinia island, ~180 km of stretched Hercynian crust form the Tyrrhenian passive margin. Strong asymmetric deformation was produced by east-dipping, low-angle detachment faults which were associated to late Miocene sediments6. Inspection of seismo-stratigraphic data (documented in Fig. 4 of ref.6) shows that N-S trending listric normal faults reduced from ~30 to 10 km the thickness of continental crust of submerged Sardinian margin, converging basinward with Vavilov plain serpentinized upper mantle (see Supplementary Information). At the plain’s eastern edge, DSDP Site 373 (Fig. 1) penetrated 190 m of basaltic crust; flows and breccias show MORB nature and K/Ar whole-rock age between ~7.5–6.3 Ma3,8,15. This dating indicates temporal overlap between Vavilov basin magmatism and hyperextension on the conjugated Sardinian margin without accompanying volcanic activity.

Figure 4

Morphology of the Vavilov Basin. Shaded relief image of Vavilov plain. Data48,49,50 and methods51,52,53,54 as in Fig. 1. It shows the N-S tectonic line linking Vavilov volcano with the peridotite swell drilled at site ODP 651 (see Fig. 6). G = Gortani ridge, 655 = site of ODP 655 drilling; D = De Marchi seamount; F = Flavio Gioia seamount; M = Magnaghi volcano; MB = Marsili Basin; Pa = Palmarola island; V = Vavilov volcano; VB = Vavilov basin. Location of seismic profile ST12 shown in Fig. 6 is indicated by a white solid line. Location of ODP 650 and DSDP 373 drillings are at the western and eastern edges of Marsili and Vavilov plains, respectively.

Such tectono-magmatic evidence indicates that late Miocene basalt crust formation of Vavilov basin preceded the Mediterranean salinity crisis (late Messinian; 5.96–5.33 Ma). The absence of evaporitic deposits in bathyal area is probably due to existing shallow water conditions3,8. Emplacement of MORB melts and exposure of serpentinized peridotite (ODP site 651) in the Vavilov basin, and hyperextension at the submerged Sardinian margin appear to recall the tectono-magmatic architecture linked to the Mesozoic continent–ocean transition at the Iberian margin6,16.

Latemost Pliocene (~1.9 – ~1.7 Ma; Olduvai subchron)

In the axial zone of Vavilov basin, inherited alpine orogen, the N-S elongated tectono-magmatic lineament linking Vavilov-volcano to exposed-peridotite8 is associated with lineated magnetic anomalies (Figs 35). The northern portion shows positive anomaly with intensity up to 70 nT (airborne survey)13. Intensity of 200 nT was obtained from shipborne data from the same area11. The southern portion of the lineament is characterized by alternating negative and positive values of magnetic field (Fig. 5b). Seismostratigraphic evidence suggests that this tectonic lineament is due to detachment faulting8. ODP Site 651 drilled through the faulted basement swell which consists of peridotites, dolerites and basalts. Such basement complexity is overlain by thin late Pliocene ooze (Globorotalia inflata zone; MPl-6; 2.6/2.4 – 1.9 Ma) which is below 340-m-thick Pleistocene sedimentary sequence (Fig. 6). Positive magnetization and foram assemblage of ooze directly overlying basement indicate that east-dipping detachment linked to mantle exposure occurred in the latemost Pliocene (LmP) - Olduvai subchron, ~1.9–~1.7 Ma. The classical scales of geological time contemplate that the Olduvai corresponds to the Tertiary/Quaternary boundary (~1.8 Ma) which separates the Pliocene from the Pleistocene portion of Matuyama chron. Based on seismostratigraphy evidence (Fig. 6), the peridotitic body was exposed through slip on east-dipping detachment fault acting in LmP time. Probably coinciding low-angle extensional faulting acted at Vavilov seamount too (Fig. 5c), without accompanying volcanic activity. Magmatism linked to the volcano-peridotite lineament is an issue of the next chapters.

Figure 5

The Vavilov volcanic complex. (a) Colour-shaded relief image based on multibeam data from ref.48. The multibeam data were processed by the Kongsberg Neptune/Poseidon packages; spatial analysis and mapping were performed using the GMT51 and PLOTMAP52 packages. Thick white line indicates the location of the cross-section shown in (c). (b) Gray-shaded relief with over-imposed contour lines (contour interval of 50 nT) of the shipborne magnetic anomaly field. Magnetic anomaly contours were digitized in geographical coordinates from ref.11 by using the software DIGMAP53 and were converted from the ED50 to the WGS84 geodetic datum by the program DATUM54. Red and blue contour lines indicate positive and negative magnetic anomalies, respectively, while zero level contour is marked by dashed-dotted line. (c) W-E cross-section of Vavilov volcano based on submersible observations from 3000 m depth to the top 684 m below sea level (see text). The summit ridge is formed by two principal eruptive centres. Vavilov volcanic complex rises from the bathyal plain at 3600 m b.s.l., and is 35 km in length and 15 km in width. (c, inspired by ref.18).

Figure 6

Stratigraphy of ODP Site 651 (Vavilov plain). (A) Main litho-stratigraphic units; the lower unit consists of complex igneous basement which has serpentinized peridotite at the bottom, whereas sediments of LmP and Pleistocene age form the upper unit. (B) Line drawing of the seismic reflection profile ST12 crossing drill-site on east flank of basement swell (see text). Location of seismic reflection profile is indicated in Fig. 4.

At the same time of Vavilov plain hyperextension, oceanic opening was initiated in Marsili basin (Fig. 4) coinciding with volcanism absence on the emerged conjugate margins. At western edge of Marsili igneous basement (Fig. 4) ODP Site 650 drilled basaltic crust with MORB transitional to calcalkaline affinity. The basalt lava is linked to round shape, positive magnetic anomaly with intensity up to 200 nT11. The forams assemblage and the positive magnetization of ooze (Trubi) directly overlying the igneous basement indicate LmP age, as at ODP Site 651. The overlying Pleistocene sequence consists of 600-m thick, sediments of terrigenous and volcanoclastic nature8,9. Being strongly altered and vesicular, the early basalt flows of Marsili plain probably erupted in shallow marine environment.

Episodes of ocean-floor moderate tensional tectonics and seamount volcanism

Pliocene (~5 – 1.9 Ma)

The N-S trending Gortani ridge was drilled at ODP Site 655 (Fig. 4). 116 m-thick basalt flows beneath only 80 m of Pliocene-Quaternary sediments show MORB affinity and 40Ar/39Ar age of 4.3 Ma10. To the west the Gortani ridge, basaltic crust is flanked by N-S elongated sedimentary basin showing > 1 sec sediment thickness6. With respect to MORB volcanism from DSDP Site 373, Gortani’s location is more distant from the W-dipping front of Adria-Ionian subduction. Such remoteness is probably a consequence of (i) past shallow depth of subducted lithosphere with little slab pull towards the active margin and/or (ii) the hyperextension that affected bathyal area and Sardinia submerged margin in late Miocene allowed Pliocene MORB volcanism migration towards the passive margin. After the Gortani, such volcanism migrated only towards the hinge zone.

ODP-651 drilling is located ~20 km to the east of Gortani ridge, and 15 km to the north of Vavilov volcano along the volcano-peridotite tectonic line, at the axis of Vavilov basin. In the northern side of lineament, serpentinized harzburgites were drilled for 30 m at the base of the well. They rest below a 135-m-thick sequence of basalt flows separated by an intrusive dolerite body8 (Fig. 6). The Site’s lower basalts of MORB composition yielded 40Ar/39Ar dating of 3.0 Ma10. The upper basalts have calc-alkaline affinity and about 2.6 Ma of age. Such datings indicate the Gauss chron for the N-S elongated positive anomaly with maximum intensity of 200 nT at ODP Site 65111. Figure 6 shows that igneous basement is overlain by 40-m-thick sterile dolostone17 which rests directly beneath LmP ooze (see previous chapter). On the other side of lineament, the magnetic anomaly field associated with Vavilov volcano shows negative and positive values11 (Fig. 6). On the basis of shipborne measurement, the northern and southern negative magnetic anomalies exhibit values up to −430 and −360 nT, respectively. The intervening positive zone with maximum intensity of + 370 nT is close to the seamount’s top. It is W-E elongated whereas the “peak-values” of normally and inversely magnetized bodies are NNE-SSW aligned with the relief axis. Seabeam bathymetry and submersible dives (Fig. 5) reveal that the west flank of Vavilov is significantly steeper than that to the east18,19. Figure 5 shows that Vavilov volcanism is divided in lower, intermediate and higher units. The lower unit (I) at waterdepth between 3.600 and 1.500 m is linked to negative anomaly. It erupted in the Pliocene portion of Matuyama chron – between 2.6/2.4 and 1.9 Ma. In fact, “Trubi-type” ooze from the western flank at 2880 m depth contains foram assemblage showing late Pliocene age. The rock was thermally indurated on contact with hot lava18. Massive pillow and bolster flows form flow-fronts that are up to 50-m-high. On the eastern flank, the basalt scarps are next to sediment-covered shelves up to 250-m wide. Flows and shelves of this flank were manifestly tilted towards the west and stretched towards the east. Their inclination towards the volcano’s axial zone was likely produced by the same east-dipping detachment faulting that exposed the peridotite swell at ODP Site 651 in LmP time (~1.8 Ma). So, the intermediate unit (II) at waterdepth of 1500–1000 m probably erupted in post-Olduvai time (<1.7 Ma). It consists of pillow flows that have <10-m-thickness and equal dip at either flank of seamount. Scoriaceous lavas of alkaline (intra-plate) nature form the upper unit - discussed below.

Quaternary (~1/0.8 Ma to Recent)

In the volcano-peridotite lineament of Vavilov basin, volcanic activity developed also in the late Pleistocene after the Matuyama/Brunhes geomagnetic reversal (<0.8 Ma)20. Figures 3 and 5 show the N-S elongated Matuyama’s negative magnetic anomaly of Vavilov volcano which is interrupted by circa E-W elongated positive anomaly11. It is located near to the top of seamount and it widens eastwards. The NNE-SSW aligned “peak-values” of normally and inversely magnetized bodies parallel the relief axis. Basalts from the upper unit are most likely linked to the Brunhes chron15. They exhibit alkaline composition and K/Ar age of ~0.4 and <0.1 Ma18,21. Alkaline basalts form by partial melting of mantle sources which are compositionally distinct from sources which experienced metasomatic modifications from subducted lithosphere at the origin of calcalkaline melts. Despite the scrupulous dives of Cyana and Mir submersibles and numerous dredge hauls, the fresh pillow flows forming the bulk of Vavilov seamount did not yield any specimen. A reason for this may be that lava detritus is overlain by sediment. Given the diversity of morphology, age and magnetic field, the chemistry of lower unit and summit lavas is probably different.

Volcanism from large Marsili seamount appears to be not older than 0.8 Ma based on the Brunhes chron and the < 0.2 Ma age of rocks dredged from the summit zone11,15,22. The seamount magnetic anomaly field, on a small scale shows transition from a lateral spreading to a pure vertical growth which probably initiated at the Jaramillo subchron23. The recovered samples constantly show calc-alkaline affinity; high-potassium andesites are present at the summit, whereas basalts from the intermediate-deep zone show medium- to low-K composition24. Voluminous volcanism of calc-alkaline affinity of the Aeolian arc developed since ~1 Ma around Marsili plain1,3 from magma sources metasomatized from subducting lithosphere.

Volcanism on the conjugated continental margins of Sardinia and Campania; their relationships with bathyal volcanism

The Rifted Continental Margin from Sardinia

The orogenic (calcalkaline) cycle

Since early Oligocene the Hercynian island of Sardinia was affected by two distinct cycles of volcanic activity with an interruption lasting ~7 Ma (Fig. 7). The Oligo-Miocene cycle of calcalkaline affinity (~30–12 Ma) developed in the N-S trending trough of western Sardinia25,26. The “Fossa Sarda” was affected by rifting concomitantly with rifting of Provence conjugated margin until ~20 Ma. At this time, continental rift reached the stage of oceanic opening of Sardinia-Provence basin and rotation of the Corsica-Sardinia block (~20–16 Ma)3,27. Andesites and ignimbrites are the main manifestations of the Oligo-Miocene volcanism. Pillow-lavas with tholeiitic, high-Mg basalt composition are associated with early Burdigalian (~20–18 Ma) shallow marine sediments from central western Sardinia28. It appears that effusion of mafic volcanics in Sardinia (~20–18 Ma) was coincident with oceanic opening of Sardinia-Provence basin.

Figure 7

The volcanic cycles from Sardinia. Simplified map showing that Sardinian volcanism developed in Oligocene-Miocene and Pliocene-(late Quaternary) time, and that pre-Pliocene sediments are found only in the “Fossa Sarda” of western Sardinia (see text). Mapping was carried out using PLOTMAP52 software with boundaries of volcanic provinces from refs25,29 digitized in geographical coordinates by using DIGMAP53 software and converted to the WGS84 geodetic datum by DATUM54 program.

The anorogenic (alkaline) cycle of Pliocene-(late Quaternary) age

The subaerial anorogenic (within-plate) cycle initiated to develop only after opening of Vavilov plain. The Pliocene basalt volcanism with varying alkaline to subalkaline composition is found in both western and eastern Sardinia29 (~5/4–2 Ma; Fig. 7). It was related to tensional tectonics which involved also Tyrrhenian seafloor. Subaerial basalt flows bordering the Orosei Gulf have been argon dated between 3.6 and 2.0 Ma30. In the distant Gulf offshore (Fig. 1), by the edge of bathyal plain ~75 km west of Vavilov seamount is the location of Magnaghi seamount. Magnaghi’s alkaline basalt lava shows ~3.0–2.7 Ma31 which recalls the age of peak alkaline basalt volcanism from Sardinia (~2.8 Ma21,29). The Magnaghi rocks represent the only known manifestation of Pliocene volcanism from the Sardinia continental slope. The within-plate cycle from Sardinia ceased to develop between ~2–0.9/0.8 Ma. The early part of this period (~1.9–1,7 Ma) saw strong extensional tectonics and initial oceanic opening of Vavilov plain and Marsili plain, respectively. The anorogenic volcanism continued to develop in late Quaternary (~0.9/0.8–0.1 Ma). Yet, it is found only in the Logudoro region (i.e., NW Sardinia), and without accompanying manifestations with subalkaline characteristics21,32. The Logudoro “basalti delle valli” and the rocks from the summit area of Vavilov volcano were related to late Quaternary tensional tectonics.

The offshore Campania margin

Seaward from Campania three sedimentary basins border on the structural high of Ponza Palmarola and Zannone islands which form the western portion of Pontine Archipelago (Fig. 8)4,33,34. To the south, very steep slope directly connects Palmarola with the bathyal domain (Fig. 4). Conversely, the basins from Palmarola and Ventotene, positioned respectively NW and SE of the structural high, are parallel to Campania coast. Ponza Ventotene and Palmarola to the west, and Ventotene and S. Stefano to the east are entirely volcanic islands, whereas at Zannone crop out also metamorphic rocks (phyllites) and sediments showing Mesozoic - Tertiary age4,35. Pontine volcanism has episodic nature33,36,37. ~4.4 Ma old rhyolites of calcalkaline affinity and ~1.1 Ma K-rich trachytes extruded at Ponza. Ponza trachytes, and 0.8-Ma-old basalts from Ventotene and S. Stefano islands are early products of the late Quaternary Roman Magmatic Region38,39. More to the east, significant K-rich volcanism of the last 0.2 Ma developed in connection with tensional and transtensional faulting in and around Ischia and Procida islands (Campanian shelf), and Phlegrean Fields and Vesuvius (Naples bay)40. The extrusion dome of Palmarola ~1.75 Ma of age (LmP) is made of rhyolites of transitional composition between calcalkaline and alkaline33,41. Palmarola rocks appear to overlap temporally the hyperextension along the lineament linking Vavilov-volcano to exposed-peridotite. Early Pliocene calcalkaline rhyolitic volcanism, and normal and wrench extension faulting initiated to form the Palmarola and Ventotene basins34. Based on seismic reflection profiling and geological data, a widespread middle-Pliocene sedimentary unconformity was recognized on the Tyrrhenian margins, and it was considered to reflect overall basin-wide subsidence42. In Vavilov plain, Gortani ridge volcanism and adjacent basin formation developed in the early Pliocene (~4.3 Ma) shortly before large-scale unconformity occurrence6,10 (Supplementary Information). Gortani’s localized tectono-magmatic manifestation has probably put an end to late-Miocene seafloor shallowness of Vavilov basaltic crust. In the Campania shelf, landward from Ventotene basin a late-Miocene to Quaternary W-E trending submerged sedimentary sequence has been recognized34. The paleo-basin of Terracina, “presently masked by the continental shelf shows a marginal, terrigenous facies type surely lacking the evaporitic rocks so characteristic of some Tyrrhenian margins”34. With time, the late Miocene W-E distensive deformation from Gaeta gulf was supplanted by NW-SE extensional tectonics and volcanic activity compatible with the youngest extension direction of Tyrrhenian basin4,40.

Figure 8

The Ponza structural high. (a) Bathymetric map showing Latium-Campania offhore, the volcanic structural high of Palmarola Ponza and Zannone islands, and the adjacent sedimentary basins of Palmarola, Ventotene and Vavilov. Data48,49,50 and methods51,52,53,54 as in Fig. 1. (b) Line drawing and interpretation of seismic reflection profile TP6 across Palmarola basin; early Pliocene sediment is found at coring station n. 20. TP6 profile shows that Capo Circeo offshore and Palmarola basin have been submerged only shallowly until early Pliocene. Palmarola basin formation and calcalkaline rhyolitic volcanism from Ponza island started in early Pliocene (4.4 Ma). Legend. Seismic unit A – Plio-Quaternary sedimentary sequence divisible in: unit A1, sedimentary sequence from the mid-Pliocene to the present including seismic unit H; unit A2, sedimentary sequence including lower and middle Pliocene. Seismic unit C – acoustic substratum divisible in: unit C1, non reflective; unit C2, reflective. X: middle Pliocene unconformity; Z: top of the acoustic substratum (see text). (b, inspired by ref.34).


The basalt - peridotite lineament of Vavilov plain

Regarding the nature of Tyrrhenian igneous basement, some authors12 suggest that the area floored by peridotite is larger than that showing basalt compostion6. From a geodynamic perspective, the former view may imply that Tyrrhenian opening was mainly forced by extensional tectonics and the latter by magmatic activity. The magmato-tectonic lineament linking Vavilov-volcano to peridotite might abut the volcanic island of Palmarola (Figs 4 and 8). LmP hyperextension along the Vavilov plain tectonic line accompanied by rhyolitic volcanism from Palmarola might announce inception of Vavilov-Marsili basaltic crust rapid subsidence. Such event was preceded by basin formation linked to high-angle faulting affecting basaltic plain and margins’ continental crust. Pliocene to Quaternary sedimentary basins are found only in submerged Sardinia margin, and in subaerial and submerged portions of Campanian margin, and may be also elsewhere6,34,43. On the Sardinia margin, ODP Site 654 drilled lava flow interbedded in Pliocene-Quaternary sedimentary sequence10 (Fig. 1). It is a basaltic andesite of LmP age, and is analogous to some subaerial Pliocene manifestations of intraplate affinity from Sardinia29. Figure 1 suggests that NW-SE trend of LmP oceanic opening supplanted the late Miocene E-W extension linked to basaltic crust formation of Vavilov plain. In the LmP episode, volcanism was localized only in marine areas. On the emersed margins of Sardinia and Campania the volcanic activity resumed to develop only about 1/0.9 Ma ago.

N-S elongated sedimentary basin showing > 1 s sediment thickness formed to the east of the LmP lineament6 (Supplementary info). Location of lineament is in the central basalt plain of Vavilov amid De Marchi and Flavio Gioia seamounts (Fig. 4). Crystalline-metamorphic basement is found at either relief. The Flavio Gioia is composed by late Hercynian granitoids and metamorphic rocks of various grade involved as tectonic units of the Alpine orogen; this crystalline-metamorphic association recalls the back-thrusts from Calabrian arc44. Conversely, the crystalline-metamorphic De Marchi relief includes tethyan ophiolites. They have been sampled in several other Tyrrhenian sites and appear to be similar to the front-thrust ophiolites from Alpine Corsica6,45. From a structural point of view, the tectonic line probably represents the collapsed geosuture linked to past double verging alpine-age crustal accretion (Fig. 2). Back-thrusted allochthons of metamorphic basement are present also in the internal side of Apennines46. The Apennines are characterized by clearly distinct modes of tectonic activity. Extensional and compressional deformation affect the thrust belt internal (Tyrrhenian) and external (Adriatic) side, respectively. Also the seismicity focal aspects of compressional and extensional type mirror the tectonic mode diversity at either Apennines side47. Extensional tectonics of the calcareous reliefs from Monti Sibillini and surroundings was at the origin of strong earthquakes and prolonged aftershock sequences from August 2016 to January 2017.

Evolution of volcanism and magnetic anomaly field

The anomalies associated with deep-seated basaltic crust have low intensity (up to 200 nT11) and shapes which are almost rounded or poorly elongated (diffusional spreading linked to strong extension and low-angle faults (the drillsites DSDP 373 and ODP 650; see inset -a- of Fig. 3). By contrast, the magnetic patterns linked to the high-standing basaltic crust (volcanoes) exhibit high intensity (up to 1500 nT) and elongated, better-organized configuration (quasi-linear spreading associated to moderate extension and high-angle faults). The elevation of elongated edifices strongly increased moving eastwards. Gortani ridge, Vavilov seamount and the over-fed Marsili seamount may be considered to be a “sui-generis” southeastward migrated sequence of N-S oriented axes of spreading.


–The Tyrrhenian opening was initiated in the late Miocene before Messinian salinity crisis and margins’ volcanism. Strong extensional deformation (drifting) was a consequence of E-directed low-angle faulting of the Sardinia offshore margin accompanied by ascent of MORB melts at the shallow eastern edge of Vavilov plain (DSDP-Site-373). Subsequent, E-directed low-angle faulting along the magmato-tectonic lineament linking Vavilov volcano to exposed peridotite acted in LmP time (~1.9–1.7 Ma). The short-lived hyperextension along Vavilov axial zone experienced concomitant opening of Marsili plain linked to emplacement of basalt melts (ODP-Site-650 at the plain western edge) without accompanying volcanism on the emerged margins.

–The post drift, Pliocene (~5/4 – 1.9 Ma) and late Quaternary (<1 Ma) basalt crust formation was characterized by moderate extension, high-angle faulting (rifting) and voluminous volcanism. Concomitantly, Pliocene volcanism developed in bathyal area and on conjugated continental margins. Early Pliocene (~4.4 Ma) MORB lava at ODP site 655 and basin formation from Vavilov plain6,10, and rhyolites from Ponza island and basin formation at Palmarola (submerged Campanian margin)33,34 probably indicate starting evolution from shallow to deep water conditions of the mafic crust.

–From a structural point of view, the volcano-peridotite lineament might represent a geosuture produced by alpine-age crustal accretion that probably implied obduction of large ultramafic bodies12. In this view of peridotitic lineament, the terms exposure/exposed can be be more appropriate than exhumation/exhumed. The lineament was affected by episodic volcanic activity from early Pliocene (ODP-Site-651; ~3.0 Ma) to late Quaternary. It likely abuts the structural high of Ponza archipelago. The extrusion of Palmarola rhyolites and hyperextension of Vavilov plain (~1.75 Ma) possibly triggered basin-scale extension change from W-E to NW-SE direction and inception of basaltic crust rapid subsidence4,33,40. Extensional tectonics and basalt volcanism of Tyrrhenian opening reflect crustal stretching of inherited alpine-age orogen, being itself related to rifting of the Apennines internal side.

Nevio Zitellini and CS produced the PDF files of article34 and articles21,24,25,29,30,33,37,38,44, respecticely. Such PDF files are found in the authors’accounts at - ResearchGate is probably the only way to obtain all this info.


  1. 1.

    Peccerillo, A. & Lustrino, M. Compositional variations of the Plio-Quaternary magmatism in the circum-Tyrrhenian area: deep- versus shallow-mantle processes. Geol. Soc. Am. Spec. Paper 388, 421–434 (2005).

    Google Scholar 

  2. 2.

    Savelli, C. Time-space distribution of magmatic activity in the western Mediterranean and peripheral orogens during the past 30 Ma (a stimulus to geodynamic considerations). J. of Geodynamics 34, 99–126 (2002).

    ADS  Article  Google Scholar 

  3. 3.

    Savelli, C. Fast Episodes of West-Mediterranean-Tyrrhenian oceanic opening and revisited relations with tectonic setting. Sci. Rep. 5, 14271 (2015).

    ADS  CAS  Article  PubMed  PubMed Central  Google Scholar 

  4. 4.

    Conti, A. et al. Transfer zones in an oblique back-arc basin setting: insights from the Latium-Campania segmented margin (Tyrrhenian Sea). Tectonics 36, 78–107, (2016).

    ADS  Article  Google Scholar 

  5. 5.

    Doglioni, C., Gueguen, E., Harabaglia, P. & Mongelli, F. On the origin of W-directed subduction zones and applications to the western Mediterranean. Geol. Soc. Spec. Publ. 156, 541–561 (1999).

    ADS  Article  Google Scholar 

  6. 6.

    Sartori, R. et al. Crustal features along a W–E Tyrrhenian transect from Sardinia to Campania margins (Central Mediterranean). Tectonophysics 383, 171–192 (2004).

    ADS  Article  Google Scholar 

  7. 7.

    Hsu, K. J. et al. Initial Reports of the Deep Sea Drilling Project, Volume 42, Part 1: Washington - U.S. Government Printing Office (1978).

  8. 8.

    Kastens, K. et al. ODP Leg 107 in the Tyrrhenian Sea: Insigths into passive margin and back-arc basin evolution. Geol. Society of America Bulletin 100, 1140–1156 (1988).

    ADS  Article  Google Scholar 

  9. 9.

    Kastens, K. & Mascle, J. The geological evolution of the Tyrrhenian Sea: an introduction to the Scientific Results of Leg 107. Proceedings of the Ocean Drilling Program Leg 107, 3–26 (1990).

    Google Scholar 

  10. 10.

    Kastens, K. et al. Proceedings of the Ocean Drilling Program, Scientific Results, College Station, TX - Ocean Drilling Program Vol. 107 (1990).

  11. 11.

    Faggioni, O., Pinna, E., Savelli, C. & Schreider, A. A. Geomagnetism and age study of Tyrrhenian seamounts. Geophys. J. Intern. 123, 915–930 (1995).

    ADS  Article  Google Scholar 

  12. 12.

    Prada, M., Ranero, C. R., Sallarès, V., Zitellini, N. & Grevemeyer, I. Mantle exhumation and sequence of magmatic events in the Magnaghi-Vavilov Basin (Central Tyrrhenian, Italy): New constraints from geological and geophysical observations. Tectonophysics 689, 133–142 (2016).

    ADS  Article  Google Scholar 

  13. 13.

    AGIP (Ital. national oil company). Magnetic map of Italy: Residual magnetic field anomalies (scale 1/500,000, sheets A-P, 1981).

  14. 14.

    Caratori Tontini, F., Stefanelli, P., Giori, I., Faggioni, O. & Carmisciano, C. The revised aeromagnetic anomaly map of Italy. Annals of Geophysics 47/5, 1547–1555 (2004).

    Google Scholar 

  15. 15.

    Savelli, C. & Schreider, A. A. Theopening processes in the deep Tyrrhenian basins of Marsili and Vavilov, as deduced from magnetic and chronological evidence of their igneous crust. Tectonophysics 190, 119–131 (1991).

    ADS  Article  Google Scholar 

  16. 16.

    Manatschal, G. New models for evolution of magma-poor rifted margins based on a review of data and concepts from West Iberia and the Alps. Int. J. Earth Sci. (Geol. Rundschau) 93/3, 432–466, (2004).

    Google Scholar 

  17. 17.

    Dekov, V. M., Kamenov, G. D., Savelli, C., Stummeyer, J. & Marchig, V. Origin of basal dolomitic claystone in the Marsili Basin, Tyrrhenian Sea. Marine Geol. 236, 121–141 (2007).

    ADS  CAS  Article  Google Scholar 

  18. 18.

    Robin, C., Colantoni, P., Gennesseaux, M. & Rehault, J. P. Vavilov seamount: a mild alkaline Quaternary volcano in the Tyrrhenian basin. Marine Geol. 78, 125–136 (1987).

    ADS  CAS  Article  Google Scholar 

  19. 19.

    Marani, M. & Gamberi, F. Distribution and nature of submarine volcanic landforms in the Tyrrhenian Sea: the arc vs the backarc. Mem. Descr. Carta Geol. d’It. 64, 109–126 (2004).

    Google Scholar 

  20. 20.

    Izett, G. A. & Obradovich J.D. 40Ar-39Ar dating of the Jaramillo normal subchron and the Matuyama and Brunhes geomagnetic boundary. U.S. Geological Survey Open-File Report 92–699 (1992).

  21. 21.

    Savelli, C. Late Oligocene to Recent episodes of magmatism in and around the Tyrrhenian Sea: implications for the processes of opening in a young inter-arc basin of intra-erogenic (Mediterranean) type. Tectonophys. 146, 163–181 (1988).

    Article  Google Scholar 

  22. 22.

    Marani, M. Super-inflation of a spreading ridge through vertical accretion. Mem. Descr. Carta Geol. d’It. 64, 185–194 (2004).

    Google Scholar 

  23. 23.

    Cocchi, L. et al. Chronology of the transition from a spreading ridge to an accretional seamount in the Marsili backarc basin (Tyrrhenian Sea). Terra Nova 21, 369–374 (2009).

    ADS  Article  Google Scholar 

  24. 24.

    Savelli, C. & Gasparotto, G. Calc-alkaline magmatism and rifting of the deep-water volcano of Marsili (Aeolian back-arc, Tyrrhenian Sea). Marine Geology 119, 137–157 (1994).

    ADS  CAS  Article  Google Scholar 

  25. 25.

    Savelli, C., Beccaluva, L., De Riu, M., Macciotta, G. & Maccioni, L. K/Ar geochronology and evolution of the Tertiary “calc-alkalic” volcanism of Sardinia (Italy). J. Volcanol. Geotherm. Res. 5, 257–269 (1979).

    ADS  CAS  Article  Google Scholar 

  26. 26.

    Lustrino, M. L. & Melluso, M. V. The geochemical peculiarity of “Plio-Quaternary” volcanic rocks of Sardinia in the circum-Mediterranean area. Spec. Paper. Geol. Soc. Am. 418, 277–301 (2007).

    Google Scholar 

  27. 27.

    Gattacceca, J. et al. Miocene rotation of Sardinia: New paleomagnetic and geochronological constraints and geodynamic implications. Earth Planet. Scie. Lett. 258/3, 359–377 (2007).

    ADS  Article  Google Scholar 

  28. 28.

    Mattioli, M., Guerrera, F., Tramontana, M., Raffaelli, G. & D’atri, M. High-Mg Tertiary basalts in Southern Sardinia (Italy). Earth Planet. Scie. Lett. 179, 1–7 (2000).

    ADS  CAS  Article  Google Scholar 

  29. 29.

    Beccaluva, L., Deriu, M., Macciotta, G., Savelli, C. & Venturelli, G. Geochronology and magmatic character of the Pliocene-Pleistocene volcanism in Sardinia (Italy). Bull.Volcanol. 40/3, 1–16 (1977).

    Google Scholar 

  30. 30.

    Savelli, C. & Pasini, G. Preliminary results of K-Ar dating of basalts from Eastern Sardinia and the Gulf of Orosei (Tyrrhenian Sea). Giornale di Geol. 39, 303–312 (1973).

    Google Scholar 

  31. 31.

    Selli, R. & Fabbri, A. Tyrrhenian: a Pliocene deep sea. Accademia Naz. Lincei, Rend. Sc. Fis. Mat. e Nat. serie VIII L, 580–592 (1971).

    Google Scholar 

  32. 32.

    Beccaluva, L., Deriu, M., Macciotta, G., Savelli, C. & Cantoni, M. Geopetrographic map of Plio-Pleistocene volcanism of NW Sardinia (scale 1:50.000). Litografia Artistica Cartografica, Firenze (1981).

  33. 33.

    Savelli, C. K/Ar ages and chemical data of volcanism in the Western Pontine Islands (Tyrrhenian Sea). Boll. Soc. Geol. It. 106, 537–546 (1987).

    CAS  Google Scholar 

  34. 34.

    Zitellini, N., Marani, M. & Borsetti, A. M. Post-orogenic tectonic evolution of Palmarola and Ventotene Basins (Pontine Archipelago). Mem. Soc. Geol. It. 27, 121–131 (1984).

    Google Scholar 

  35. 35.

    Segre, A. G. Biogeografia dell’isola di Zannone. Morfologia e geologia. Rendiconti Accademia Naz. dei XL 5, 1–16 (1954).

    Google Scholar 

  36. 36.

    Conte, A. M. & Savelli, C. Vulcanismo orogenico dell’ Isola di Ponza: rioliti calcalcaline ed evoluzione trachiti-> comenditi di serie shoshonitica. Mem. descr. Carta Geol. d’It. 49, 333–346 (1994).

    Google Scholar 

  37. 37.

    Savelli, C. Evoluzione del vulcanismo cenozoico (da 30 Ma al presente) nel Mar Tirreno e nelle aree circostanti: ipotesi geocronologica sulle fasi dell’espansione oceanica. Cenozoic volcanism evolution in Tyrrhenian sea and surroundings. Mem. Soc. Geol. It. 27, 111–119 (1984).

    Google Scholar 

  38. 38.

    Metrich, N., Santacroce, R. & Savelli, C. Ventotene a potassic Quaternary volcano in the central Tyrrhenian sea. Rendiconti Soc. Ital. Mineral. Petrogr. 43, 1195–1213 (1988).

    Google Scholar 

  39. 39.

    D’Antonio, M., Civetta, L. & Di Girolamo, P. Mantle source heterogeneity in the Campanian Region (South Italy) as inferred from geochemical and isotopic features of mafic volcanic rocks with shoshonitic affinity. Mineralogy and Petrology 67/3, 163–192, (1999).

    ADS  Article  Google Scholar 

  40. 40.

    Cuffaro, M. et al. The Ventotene volcanic ridge: a newly explored complex in central Tyrrhenian sea (Italy). Bull. Volcanol. 78(86), 1–19, (2016).

    Google Scholar 

  41. 41.

    Conte, A. M. et al. New insights on the petrology of submarine volcanics from the Western Pontine Archipelago (Tyrrhenian Sea, Italy). J. Volcanol. and Geothermal Res. 327, 223–239 (2016).

    ADS  CAS  Article  Google Scholar 

  42. 42.

    Selli, R., Lucchini, F., Rossi, P. L., Savelli, C. & Del Monte, M. Dati geologici, geochimici e radiometrici sui vulcani centrotirrenici. Giornale di Geol. 42, 221–246 (1977).

    Google Scholar 

  43. 43.

    Loreto, M. F. et al. Geophysical investigation of Pleistocene volcanism and tectonics offshore Capo Vaticano (Calabria, southeastern Tyrrhenian Sea). J. of Geodyn. 90, 71–86 (2015).

    ADS  Article  Google Scholar 

  44. 44.

    Dal Piaz, G. V., Del Moro, A., Di Sabatino, B., Sartori, R. & Savelli, C. Geologia del Monte Flavio Gioia (Tirreno Centrale). Memorie di Scienze Geol. Univ,. Padova 35, 429–452 (1983).

    Google Scholar 

  45. 45.

    Colantoni, P., Fabbri, A., Galignani, P., Sartori, R. & Rehault, J. P. Lithologic and stratigraphic map of the Italian seas (scale 1:1.500). Litografia Artistica Cartografica, Firenze (1981).

  46. 46.

    Doglioni, C., Mongelli, F. & Pialli, G. P. Boudinage of the Alpine belt in the Apenninic back-arc. Mem. Soc. Geol. It. 52, 457–468 (1998).

    Google Scholar 

  47. 47.

    Chiarabba, C., Jovane, L. & DiStefano, R. A new view of Italian seismicity using 20 years of instrumental recordings. Tectonophys 395, 251–268, (2005).

    Article  Google Scholar 

  48. 48.

    Marani, M. P. et al. Tyrrhenian sea bathymetry, In From Seafloor to Deep Mantle: Architecture of the Tyrrhenian Backarc Basin, Vol. 44 ofMem. Descr. Carta Geologica d’Italia, eds Marani, M.P., Gamberi, F. & Bonatti, E., APAT, Roma (2004).

  49. 49.

    Bortoluzzi, G. et al. Interactions between volcanism and tectonics in the Western Aeolian sector, southern Tyrrhenian Sea. Geophysical Journal International 183, 64–78 (2010).

    ADS  Article  Google Scholar 

  50. 50.

    Ligi, M. et al. Mapping of seafloor hydrothermally altered rocks using geophysical methods: Marsili and Palinuro seamounts, southern Tyrrhenian Sea. Economic Geology 109, 2103–2117 (2014).

    Article  Google Scholar 

  51. 51.

    Wessel, P., Smith, W. H. F., Scharroo, R., Luis, J. F. & Wobbe, F. Generic Mapping Tools: Improved version released. EOS Transactions of AGU 94, 409–410 (2013).

    ADS  Article  Google Scholar 

  52. 52.

    Ligi, M. & Bortoluzzi, G. PLOTMAP: Geophysical and Geological Applications of good standard quality cartographic software. Computers & Geosciences 15, 519–585 (1989).

    ADS  Article  Google Scholar 

  53. 53.

    Bortoluzzi, G. & Ligi, M. DIGMAP: a computer program for accurate acquisition by digitizer of geographical coordinates from conformal projections. Computers & Geosciences 12, 175–197 (1996).

    ADS  Article  Google Scholar 

  54. 54.

    Ligi, M. & Bortoluzzi, G. DATUM: a FORTRAN 77 Computer Program for datum shift and conversion of geographical coordinates between different cartographic systems. Computers & Geosciences 15, 449–518 (1989).

    ADS  Article  Google Scholar 

Download references


Research sponsored by PRIN2012 Programm (grant no. 20125JKANY_002). C. S. acknowledges V. Yastrebov and A. Schreider (Shirshov Institute of Oceanology, Russian Academy of Sciences) for the opportunity to participate in insightful geological-geophysical cruises in Tyrrhenian sea. In this article were used only published data which all are properly cited in the text. The quality of manuscript was improved by insightful examination of two anonymous reviewers.

Author information




C.S. and M.L. jointly produced text and figures of the article.

Corresponding author

Correspondence to Carlo Savelli.

Ethics declarations

Competing Interests

The authors declare that they have no competing interests.

Additional information

Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Electronic supplementary material

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Savelli, C., Ligi, M. An updated reconstruction of basaltic crust emplacement in Tyrrhenian sea, Italy. Sci Rep 7, 18024 (2017).

Download citation

Further reading


By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.


Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing