Quantification of Alpine Metamorphism in the Edolo Diabase, Central Southern Alps

Abstract

The Southern Alps are the retro-vergent belt of the European Alps that developed from Late Cretaceous subduction to Neogene times. The most prominent Alpine thrusts and folds, nowadays sealed off by the Adamello intrusion, were already developed before the continental collision and clasts derived from the eroded pre-collisional wedge can be found in the Cretaceous foredeep sequences. In contrast, the thermal state attained by the Southern Alps during the long-lasting Alpine evolution is still unknown. This contribution provides evidence for Alpine metamorphism in the northern part of the central Southern Alps. Metamorphic conditions are determined for the alkaline Edolo diabase dykes that emplaced in the exhumed Variscan basement rocks before being deformed during the Alpine convergence (D3). The Alpine foliation in the Edolo diabase dykes is marked by actinolite, biotite, chlorite, epidote, albite, and titanite and it developed under greenschist facies conditions at temperature of 350–420 °C and pressure ≤0.2 GPa. The T/depth ratio indicates a minimum of 50–60 °C/km that is compatible with thermal gradients characteristic of arc settings. Based on radiometric ages from the literature, these conditions were attained during the Alpine subduction.

1. Introduction

Crustal thickening due to continental collision is well documented in the external domains of the Alps since the late Eocene (e.g., [1,2,3] and refs. therein). At that time, flysch deposits and molasses filled the Alpine foreland basins (e.g., [4] and refs. therein) and collisional structures developed in the Helvetic domain under greenschist facies conditions (e.g., [5,6,7,8,9]). Differently, crustal thickening in the Alpine retro-belt (the Southern Alps) started as early as the Late Cretaceous during oceanic subduction and lasted up to post-collisional stages in Eocene to Neogene times [10,11].

Alpine metamorphic minerals are already recognized in the central Southern Alps, but a tectonic interpretation of the Alpine metamorphism is lacking [12,13,14,15,16,17,18,19,20,21]. In this contribution, we quantify the Alpine metamorphism in the northern part of the central Southalpine basement, focusing on the alkaline Edolo diabase dykes [22] and combining high-resolution structural analysis with mineral chemistry and P-T estimates. The P-T conditions estimated for the metamorphism in the Edolo diabase dykes are here used to depict the thermal state affecting the Alpine retro-belt during the Alpine convergence.

2. Geological Setting

The Alpine convergence involved the subduction of the Alpine Tethys Ocean underneath the Adria plate and the subsequent continental collision with the European lithosphere in Cretaceous to Oligocene times [1,2,3]. The Southalpine domain is that portion of Adria plate that was affected by thrusting and folding at shallow crustal levels in the Alpine retro-belt [23].

The Southalpine domain west of the icarie fault consists of Variscan basement rocks and early Permian to Cretaceous sedimentary sequences (Figure 1; [16,19,24,25] and refs. therein). To the north, this domain is separated from the other tectonic units of the Alps by the Periadriatic fault system (Figure 1), a regional scale dominantly strike-slip system that has been active at least since the Oligocene, concurrently with the Bregaglia and Adamello calc-alkaline intrusions [26,27,28,29]. This tectonic lineament separates continental and oceanic units belonging to the axial part of the chain that during the Alpine convergence experienced intense deformation and metamorphism (the Austroalpine and Penninic domains) from rocks belonging to the upper plate (the Southalpine domain) that recorded deformation at shallow structural levels (e.g., [30,31,32,33]).

The basement of the central Southern Alps consists of different tectono-metamorphic units (TMUs) that heterogeneously record the Variscan evolution and, in the Como Lake area, also the high thermal signature of the Triassic rifting [16,34,35,36]. The dominant fabric in the Variscan basement in the Adamello area is the late-Variscan S2 foliation, which developed under greenschist facies conditions during coupling of Variscan basement rocks retaining contrasting tectono-metamorphic evolutions (TMUs; [25,36,37] and refs. therein). A minimum age for S2 is constrained by the deposition of Permian siliciclastic sequences, which contain clasts deriving from the Variscan TMUs [19,24,25,38,39,40,41,42,43]. Variscan Pre-D2 foliations are marked by epidote-amphibolite and/or amphibolite facies minerals ([24,25,37] and refs. therein).

The main Alpine feature of the central Southern Alps is the south-verging Orobic–Porcile–Gallinera thrust system (Figure 1) that has brought Variscan basement rocks onto Permian to Mesozoic covers (e.g., [15,18,20,44,45,46,47,48]). In the footwall, anticlines involving basement and Permian–Mesozoic sequences - i.e. Orobic, Trabuchello–Cabianca, and Cedegolo anticlines (Figure 1) - are interpreted as fault-bend folds formed during on-going southward thrusting in pre-Oligocene times [11,13,14]. In the hanging wall, the most prominent Alpine structures are steeply dipping chevron folds in the Variscan basement (e.g., [16,21,47]). The Adamello calc-alkaline batholith, dated at 43–33 Ma ([49] and refs. therein), crosscuts the Orobic–Porcile–Gallinera thrust system and Cedegolo anticline (Figure 1; [13,14]). A further reactivation of the Periadriatic fault system and Orobic–Porcile–Gallinera thrust system, mostly as dextral strike-slip or transpressional faults, has been envisaged since the late Eocene ([11] and refs. therein).

The age of the syn-subductive activity of the Orobic–Porcile thrust system is constrained by ${}^{40}$Ar/${}^{39}$Ar dating of pseudo-tachylytes at 80–43 Ma ([10] and refs. therein), whereas Cenomanian–Campanian flysches in the southernmost part of the central Southern Alps testify the erosion of both basement and cover units on an active margin propagating southwards [50]. Poorly investigated greenschist facies mylonites are supposed to have accommodated first increments of crustal shortening before the Oligocene (e.g., [17,20,47]). Barometric estimates on pseudotachylites along the Southern Grigna Fault (Figure 1) indicate that this portion of central Southern Alps was buried up to depth equivalent to 0.1–0.2 GPa during the Alpine convergence [51].

Calc-alkaline mafic dykes are widespread in the central Southern Alps (Figure 1), where they crosscut regional scale thrusts and folds in the Variscan basement and Permian to Mesozoic sedimentary sequences [52,53]. The age of these intrusives ranges between 42 and 34 Ma [52,53], confirming that most of the central Southern Alps architecture already existed before the Oligocene [10,11,13,14].

Other mafic dykes, historically known as “Edolo diabases” [22,53], occur between the Periadriatic fault system and Gallinera Thrust (Figure 1). These dykes are characterized by alkaline affinity and are crosscut by the Adamello tonalite. For these reasons a Triassic emplacement is supposed by Italian authors of the past century [22]. Magmatic minerals are dark brown amphibole and biotite, pink clinopyroxene, plagioclase, ilmenite, magnetite, and rare quartz. Mineral assemblages and whole rock composition [22,53] allow classifying the Edolo diabases as camptonites, a type of alkaline lamprophyres [54,55].

Figure 1. Tectonic outline of the central Southern Alps (modified after [11,24,36] and refs. therein). Projected coordinate system: WGS84-UTM32N. Abbreviations–CE: Cedegolo anticline; GL: Gallinera thrust; MF: Musso fault; OA: Orobic anticline; OT: Orobic thrust; PT: Porcile thrust; SGF: Southern Grigna fault; TC: Trabuchello–Cabianca anticline; VGT: Val Grande fault. Adamello ages are from [49]; Bregaglia ages are from [28]; Alpine pseudo-tachylyte ages are from [10]; Tertiary calc-alkaline dyke ages are from [53]. The light green arrow points the studied area.

Figure 1. Tectonic outline of the central Southern Alps (modified after [11,24,36] and refs. therein). Projected coordinate system: WGS84-UTM32N. Abbreviations–CE: Cedegolo anticline; GL: Gallinera thrust; MF: Musso fault; OA: Orobic anticline; OT: Orobic thrust; PT: Porcile thrust; SGF: Southern Grigna fault; TC: Trabuchello–Cabianca anticline; VGT: Val Grande fault. Adamello ages are from [49]; Bregaglia ages are from [28]; Alpine pseudo-tachylyte ages are from [10]; Tertiary calc-alkaline dyke ages are from [53]. The light green arrow points the studied area.

3. Field Occurrence

The studied rocks are located between the Gallinera Thrust and the Periadriatic fault system in the northern part of the central Southern Alps (Figure 1). This area comprises Variscan basement rocks including metapelites, quartzites, minor metabasites, and marbles, in which the dominant fabric is the S2 Variscan foliation marked by low greenschist facies minerals. Upper greenschist to epidote amphibolite facies minerals are relics in low strain domains [19,21]. South of the Gallinera Thrust, S2 is truncated by Permian cover sequences (e.g., [19,25]).

The Alpine deformation (D3) in the Variscan basement results in localized chevron folds of metric wavelength (Figure 2), locally associated with differentiated axial plane foliation (S3). D3 structures are intersected by the Adamello towards the east and by calc-alkaline mafic dykes in different localities [13,14,16,17,19,21,47,53,56]. Biotite- and amphibole-bearing S3 Alpine foliation has been already described in pre-Alpine mafic dykes at the junction between the Porcile and Orobic thrusts [20]. D3 structures are interpreted as syn-kinematic with the Orobic–Porcile–Gallinera thrust system [16,17,21,47] whose age is constrained between 80 and 43 Ma ([10] and refs. therein).

The Edolo diabase occurs in up to 50 m-thick dykes that are mostly characterized by medium grained phaneritic texture (Figure 2), whereas the thinnest dykes are porphyritic [21,22]. The intrusive contacts with country rocks are characterized by fine grain size. Locally, the dykes host albite-rich late-intrusive veins. The Edolo diabase dykes truncate S2 in the host Variscan basement rocks and are weakly folded (D3) and intersected by the Alpine foliation S3 (Figure 2).

4. High Resolution Mapping

Structural mapping has been performed at 1:1000 scale along the road-cut between Nembra and Vico villages, less than 2 km west of Edolo (Figure 3). Here, the Edolo diabase dykes are hosted in micaschists, quartz-schist, and quartzite. NNW-dipping S2 is the dominant fabric of the host rocks and is marked by chlorite, white mica, and quartz ribbons; in low-strained domains, the older Variscan foliation (S1) is preserved along D2 isoclinal fold limbs. Alpine D3 folds are chevron-type and metric in wavelength, with sub-horizontal NE-SW trending axes (A3), axial planes (PA3) steeply dipping towards NW or SE (Figure 3), locally associated with an axial plane foliation (S3). The orientation of D2 and D3 structures in the studied area is compatible with that of D2 and D3 structures north of the Orobic–Porcile–Gallinera thrust system (Figure 3; [16,18,20,21,47,48,57]). Geometric compatibility and coherent overprinting relationships between D2 and D3 allow us to interpret D3 structures as Alpine in age, in agreement with the detailed structural analysis performed at regional scale. (e.g., [19,21] and refs therein).

Meter-thick E-W striking Edolo diabase dyke walls are steeply dipping and truncate S2 (Figure 3). Although the limited exposure precludes continuous dyke wall mapping along strike, the detailed structural analysis reveal that the dykes are gently folded during D3, in contrast to the prominent D3 folds recorded in the country rocks. Despite of gentle folding, S3 is locally developed within the Edolo diabase dykes (Figure 3). Within the dykes, S3 strike deviates at least 20° from that of the dyke walls and matches the orientation of PA3 and S3 in the host rocks (Figure 3). Kink-bands, cataclastic shear zones, and minor faults intersect all the structures and lithotypes (Figure 3).

5. Microstructure

Edolo diabase dykes are composed of euhedral to subhedral crystals of magmatic (I) clinopyroxene (CpxI), amphibole (AmpI), brown biotite (BtI), plagioclase (PlI), ilmenite (IlmI), and apatite (Figure 4). The dyke margins are often porphyritic with millimeter-sized phenocrysts of AmpI, CpxI, and BtI in an aphanitic groundmass. Cores of magmatic amphiboles are dark brown (AmpI₁), locally with pale brown rims (AmpI₂). CpxI is pale pink, core to rim zoned (CpxI${}_1$ to CpxI${}_2$) and locally rimmed by BtI, AmpI${}_1$, or AmpI${}_2$. Rare ilmenite grains (IlmI) are included in CpxI, AmpI, and BtI. Magmatic plagioclase (PlI) is zoned, with simple to polysynthetic growth-twinning at cores and no twinning at rims. In the phaneritic dykes, interstitial domains between laths of PlI are filled by BtI, AmpI${}_2$, rare quartz grains, and magmatic epidote (EpI, Figure 4). At rims, EpI is partially replaced by fine-grained aggregates of metamorphic epidote.

Magmatic minerals are locally replaced by post-magmatic mineral assemblages, namely M${}_1$ and M${}_2$. M${}_1$ minerals display coronitic texture and pre-date the Alpine foliation S3. AmpI, BtI, and CpxI are rimmed by coronitic pale green/colorless amphibole (AmpM${}_1$), chlorite (ChlM${}_1$), titanite (TtnM${}_1$), epidote (EpM${}_1$), pyrite, and rare calcite (Figure 4). M${}_1$ minerals are interpreted as related to late- to post-magmatic hydrothermal circulation, which affected the dykes soon after their emplacement.

The Alpine S3 foliation in the Edolo diabase dykes is pervasive in centimeter-thick cleavage bands and is marked by M${}_2$ minerals (Figure 4), including amphibole (AmpM${}_2$), biotite (BtM${}_2$), chlorite (ChlM${}_2$), epidote (EpM${}_2$), plagioclase (PlM${}_2$), and titanite (TtnM${}_2$)-rich stylolitic films. M${}_2$ minerals fill D3 syn-kinematic boudin necks and pressure-shadows around magmatic and M${}_1$ minerals (Figure 4). M${}_2$ minerals also support micro-shear surfaces at a low angle with S3. In the high strained domains magmatic plagioclase grains are fractured. Pre-Alpine AmpM${}_1$-rich veins are transposed along S3 (Figure 4). M${}_2$ minerals form coronae around magmatic and M${}_1$ hydrothermal minerals in the low-strained domains.

In quartzites, the dominant S2 foliation is marked by preferred orientation of medium- to coarse-grained quartz lithons and films rich in opaque minerals and rare white mica. In quartz-schists, white mica and elongated opaque mineral films mark the dominant foliation S2. Often these rocks record D3 Alpine thight folds with quartz layers thickened in the hinge zone. In micaschists, the pervasive S2 foliation is marked by white mica and chlorite. Rare tourmaline shows sharp grain boundaries against white mica marking S2. Only locally, quite fresh biotite is particularly abundant in the films of S2 along with relict biotite crystals between films. Quartz occurs in micro-lithon domains. White mica and biotite prophyroclasts are wrapped by S2, the latter partially replaced by chlorite and white mica and quartz filling the strain-shadows. Relict porphyroclasts are completely replaced by white mica and chlorite. Folded S1 foliation is marked by quartz layers and white mica films. S2 foliation is crenulated by D3 Alpine folds and the rare crenulation cleavage S3 is marked by white mica and chlorite.

6. Mineral Chemistry

Two foliated (S3) samples of Edolo diabase (Ge8, Ge11; Figure 3) were analyzed at Università degli Studi di Milano with a JEOL 8200 Super Probe (WDS) at 15 kV accelerating voltage and with a beam current of 5 nA; natural silicates served as standards. Amphibole formulae are calculated using Locock’s amphibole classification spreadsheet [58] and following IMA 2012 recommendations. Clinopyroxene formula is recalculated at 4 cations and 6 O, feldspar at 4 O, epidote at 8 cations and 12.5 O. Biotite and chlorite are recalculated at 11 and 7 O, respectively. Representative mineral analyses are in Table S1.

6.1. Magmatic Minerals

CpxI${}_1$ (X${}_{Mg}$ = 0.69–0.78) and CpxI${}_2$ (X${}_{Mg}$ = 0.63–0.68) are diopside, with CpxI${}_1$ slightly Al- and Ti- richer (Al = 0.14–0.30 apfu, Ti = 0.04–0.08 apfu) than CpxI${}_2$ (Al = 0.05–0.18, Ti = 0.00–0.04 apfu).

AmpI${}_1$ (Figure 5) is ferri-kaersutite, Ti-rich ferro-pargasite, or Ti-rich magnesio-hornblende, with Si = 5.99–6.34 apfu, Ti = 0.45–0.64 apfu, and Al = 1.90–2.32 apfu. AmpI${}_1$ is characterized by Na varying from 0.40 to 0.86 apfu and K from 0.18 to 0.25 apfu, as reflective of the alkaline affinity of the Edolo diabase dykes (cfr. [59]). AmpI${}_1$ X${}_{Mg}$ in sample Ge8 (0.45–0.49) is slightly lower than in sample Ge11 (0.49–0.66).

AmpI${}_2$ (Figure 5) is (Ti-rich) ferro-pargasite similar to AmpI${}_1$ in terms of Si, Al, Na, and K contents, but markedly Ti poorer (Ti = 0.14–0.44 apfu) and Fe richer (X${}_{Mg}$ = 0.16–0.33), with the lowest X${}_{Mg}$ values in sample Ge8. BtI is characterized by Al${}^{VI}$ from 0.00 to 0.38 apfu and Ti from 0.37 to 0.78 apfu. BtI X${}_{Mg}$ in sample Ge8 (0.43–0.44) is lower than in sample Ge11 (0.44–0.49).

Zoned PlI is An${}_{40-58}$ at core, An${}_{10-38}$ between core and rim, and An${}_{7-8}$ at rim. EpI filling interstices between PlI is characterized by Fe${}^{3+}$ = 0.36–0.53 apfu and Al${}^{VI}$ = 2.47–2.64 apfu; EpI rimming BtI is Fe${}^{3+}$ richer (0.54–0.59 apfu) and Al${}^{VI}$ poorer (2.41–2.46 apfu).

6.2. Metamorphic Minerals

Even though the magmatic evolution comes along with strong compositional heterogeneities at the grain scale, hereafter we focus on the compositional trends observed in metamorphic minerals. Furthermore, a more detailed microstructural classification is proposed in Figure 5 to show the reader the local effects of the inherited compositional heterogeneities.

AmpM${}_1$ (Figure 5) is actinolite with Si = 7.78–7.93 apfu, Al${}^{VI}$ = 0.02–0.09 apfu, and very low to negligible Ti and Na content (Ti = 0.00–0.02 apfu, ${}^B$Na = 0.01–0.05 apfu, ${}^A$Na = 0.00–0.04 apfu). X${}_{Mg}$ in AmpM${}_1$ is higher in sample Ge11 (0.71–0.77) than in sample Ge8 (0.65–0.53), with the lowest X${}_{Mg}$ values where AmpM${}_1$ replaces Fe-rich AmpI${}_2$. ChlM${}_1$ is characterized by Al${}^{IV}$ = 0.92–1.09 apfu and X${}_{Mg}$ = 0.46–0.56; EpM${}_1$ by Fe${}^{3+}$ = 0.85–0.93 apfu and Al${}^{VI}$ = 2.07–2.14 apfu.

AmpM${}_2$ (Figure 5) is actinolite or magnesio-ferri-hornblende, with Si = 7.42–7.83 apfu, Al${}^{VI}$ = 0.04–0.17 apfu, and Ti < 0.04 apfu. The Na content in AmpM${}_2$ (${}^B$Na = 0.02–0.10 apfu, ${}^A$Na = 0.02–0.13 apfu) is higher than in AmpM${}_1$. Even in this case, AmpM${}_2$ X${}_{Mg}$ in sample Ge11 (0.59–0.81) is generally higher than in sample Ge8 (0.53–0.64), with AmpM${}_2$ replacing AmpI${}_2$ characterized by the Fe-richest compositions. BtM${}_2$ (X${}_{Mg}$ = 0.49–0.54) is characterized by Si = 5.38–5.70 apfu, Al${}^{VI}$ = 0.46–0.61 apfu, and Ti = 0.06–0.16 apfu (Figure 5). In ChlM${}_2$ (X${}_{Mg}$ = 0.49–0.55 in sample Ge8, and 0.56–0.59 in sample Ge11) Si is 2.63–2.91 apfu and Al${}^{IV}$ is 1.10–1.37 apfu. EpM${}_2$ is characterized by Fe${}^{3+}$ = 0.75–0.85 apfu and Al${}^{VI}$ = 2.15–2.24 apfu (Figure 5). PlM${}_2$ is An${}_{2-7}$.

Consistent compositional trends characterize the transition from late- to post-intrusive hydrothermalism (M${}_1$) to Alpine metamorphism (M${}_2$) associated with S3 development:

• decrease in Fe${}^{3+}$ and increase in Al${}^{VI}$ from EpM${}_1$ to EpM${}_2$,
• increase in Al${}^{IV}$ from ChlM${}_1$ to ChlM${}_2$,
• decrease in Si and increase in Al${}^{VI}$, ${}^A$Na, and ${}^B$Na content from AmpM${}_1$ to AmpM${}_2$.

These trends are diagnostic of a prograde metamorphic evolution through the greenschist facies in mafic rocks (e.g., [60,61] and refs. therein).

7. Metamorphic Evolution

Mineral associations and compositional trends suggest that the metamorphic evolution of the Edolo diabase dykes entirely took place under greenschist facies conditions. It is well known that, under these conditions, equilibrium is often attained only at a very local scale in mafic rocks due to slow reaction progress in the absence of fluids and P-T estimates come along with a wide margin of error [62]. In addition, we have already shown that local compositional heterogeneities inherited from the magmatic evolution persist in these rocks (Figure 4 and Figure 5), making it unwise to use bulk rock data to represent local equilibrium volumes. Taking into account these reasons, we try to constrain the P-T evolution of the Edolo diabase by matching different thermo-barometric methods involving chlorite and amphibole. For chlorite the thermometers that are most suitable in low- to very low-grade rocks [63,64] and avoid the issue of Fe oxidation-state determination (see [64] for a discussion) have been used, even though T > 350 °C should be considered with caution. The same approach was applied in selecting the amphibole thermometers, recalculating the minerals following the procedures suggested by respective authors [65,66,67] and using only those thermobarometers where greenschist facies conditions are considered.

Chlorite and amphibole thermometry constrain late- to post-intrusive hydrothermal conditions (M${}_1$). According to ChlM${}_1$ thermometry (

Table 1. Thermobarometric constraints on M${}_1$ and M${}_2$ minerals.

Metamorphic Stage	Microstructure	T${}_{\mathit{Chl}}$ [63,64]	T${}_{\mathit{Amp}-\mathbf{Pl}}$ [65,67]	P${}_{\mathit{Amp}}$ [66,67]
M${}_1$		230–290 °C (n = 3)	290 °C < T ≪ 490 °C (n = 12)	≪0.2 GPa (n = 12)
M${}_2$		300–420 °C (n = 16)	350 °C ≤ T < 490 °C (n = 41)	≤0.2 GPa (n = 41)

; [63,64]), temperatures are slightly lower than 300 °C, while AmpM${}_1$ thermometry suggest temperatures at around 350 °C (Table 1; [65]).

The physical conditions of Alpine metamorphism (M${}_2$) are constrained by chlorite and amphibole thermobarometry. ChlM${}_2$ thermometry [63,64] returns temperatures between 300 and 420 °C (Table 1). However, these authors reccomend caution when dealing with results above 350 °C. Temperatures above 350 °C are indicated by AmpM${}_2$ thermometry ([65], Figure 6), whereas pressures up to 0.2 GPa are indicated by AmpM${}_2$ barometry ([66,67], Figure 6).

A further constrain on the P-T evolution of the Edolo diabase dykes comes from the country rocks, where S3 is marked by chlorite and white mica. We thus consider the biotite appearance at a temperature of 420 °C [62] as the upper temperature boundary for the Alpine metamorphic evolution of the Edolo diabase. Therefore we suggest that Alpine P-T conditions are constrained between T = 350–420 °C and P ≤ 0.2 GPa (Figure 6).

8. Discussion

North of the Orobic–Porcile–Gallinera thrust system, the alkaline Edolo diabase dykes are crosscut by Alpine S3 foliation. In the dykes, S3 is marked by Al- and Na-rich actinolite (AmpM${}_2$), biotite (BtM${}_2$), chlorite (ChlM${}_2$), epidote (EpM${}_2$), albite (PlM${}_2$), and titanite. In the host metapelites, S3 is instead marked by white mica, chlorite, and opaque minerals. S3 development is kinematically correlated with the development of the Orobic–Porcile–Gallinera thrust system (D3) and chevron-type D3 folding in the Variscan basement rocks [16,20,21,47,48].

Taking into account textural and compositional heterogeneities in the samples, their influence on the determination of equilibrium P-T conditions, and the intrinsic error of the thermo-barometric methods at low grade metamorphic conditions, we suggest that S3 developed in the Edolo diabase at T = 350–420 °C and P ≤ 0.2 GPa, as indicated by overlapping thermo-barometric estimates. These P-T conditions are the first quantitative estimates of Alpine metamorphic conditions in the Southern Alps that were attained during a prograde evolution following a former re-equilibration stage (M${}_1$) at T ≤ 350 °C related to post-intrusive hydrothermal circulation.

Metamorphic assemblages that suggest P-T conditions similar to those estimated for the Edolo diabase dykes are also described in the pre-Alpine mafic dykes at the junction between the Orobic and Porcile thrusts ([20], Figure 1), indicating that also the western edge of the Orobic–Porcile thrust nappe recorded the same metamorphic imprint during the Alpine convergence. The onset of south-verging shortening (syn-D3) in the Southern Alps occurred during oceanic subduction, as indicated by the 80–43 Ma ${}^{40}$Ar/${}^{39}$Ar ages of the Orobic–Porcile thrusts [10,11] in comparison with the ages of HP rocks in the exhumed Alpine subduction zone ([1,2,3] and refs. therein). This time interval is therefore considered for the upper greenschist facies Alpine metamorphism (M${}_2$) recorded in the Edolo diabase dykes.

The obtained P-T conditions suggest a minimal T/depth ratio of 50–60 °C that is compatible with volcanic arc geothermal gradients (e.g., [69,70,71], Figure 7). Such perturbed thermal state in the upper-plate of the Alpine subduction system can also explain the genesis of the syn-subductive magmatism south of the Periadriatic fault system, in the Veneto volcanic province (∼40 Ma, [72] and ref. therein) and in the southern Adamello pluton (43–41 Ma, [73,74]).

9. Conclusions

In this contribution we investigated the thermal state attained by the upper plate of the Alpine subduction system, i.e., the central Southalpine domain, looking at the structural and metamorphic evolution retained by the Edolo diabase dykes north of the Orobic–Porcile–Gallinera thrust system and south of the Periadriatic fault system. The dykes retain two metamorphic events, the first (M${}_1$) at T < 350 °C interpreted as due to a post-intrusive hydrothermal activity and the second (M${}_2$) at T = 350–420 °C, P ≤ 0.2 GPa, which is syn-kynematic with the development of D3 south-verging Alpine thust system between 80 and 43 Ma. M${}_2$ metamorphism developed under a thermal state compatible with a syn-subductive volcanic arc. South of the Periadriatic fault system, which borders the exhumed Alpine subduction zone, magmatic bodies emplaced intersecting D3 structures during active Alpine subduction in Eocene times.