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1. Quaternary Melanephelinites and Melilitites from Nowbaran (NW Urumieh-Dokhtar Magmatic Arc, Iran): Origin of Ultrabasic-Ultracalcic Melts in a Post-Collisional Setting

Author

Lustrino M.[1, Salari G.[1], Rahimzadeh B.[3], Fedele L.[4], Masoudi F.[3], Agostini S.[5], Lustrino, M., Salari, G., Rahimzadeh, B., Fedele, L., Masoudi, F., and Agostini, S.

Subjects
Geophysics, Geochemistry and Petrology, Ultramafic rock, Back-arc basin, igneous petrology, nephelinite, melilitite, subduction, ultrabasic, Iran, carbonatite, geochemistry, igneous petrology, nephelinite, subduction, ultrabasic, Iran, carbonatite, geochemistry, Geochemistry, Quaternary, Geology
Abstract

The small Quaternary volcanic district of Nowbaran (NW Iran) belongs to the Urumieh-Dokhtar Magmatic Arc, a ~1800 km long NW-SE striking Cenozoic belt characterized by the irregular but abundant presence of subduction-related igneous products. Nowbaran rocks are characterized by absence of feldspars coupled with abundance of clinopyroxene and olivine plus nepheline, melilite and other rarer phases. All the rocks show extremely low SiO2 (35.4-41.4 wt%), very high CaO (13.1-18.3 wt%) and low Al2O3 (8.6-11.6 wt%), leading to ultracalcic compositions (i.e., CaO/Al2O3 >1). Other less peculiar, but still noteworthy, characteristics are the high MgO (8.7-13.3 wt%) and Mg# (0.70-0.75), coupled with a variable alkali content with sodic affinity (Na2O = 1.8-5.4 wt%; K2O = 0.2-2.3 wt%) and variably high LOI (1.9-10.4 wt%; average 4.4 wt%). Measured isotopic ratios (87Sr/86Sr = 0.7052-0.7056; 143Nd/144Nd = 0.51263-0.51266; 206Pb/204Pb = 18.54-18.66; 207Pb/204Pb = 15.66-15.68; 208Pb/204Pb = 38.66-38.79) show small variations and plot within the literature field for the Cenozoic volcanic rocks of western Iran but tend to be displaced towards slightly higher 207Pb/204Pb. Primitive mantle-normalized multielemental patterns are intermediate between typical subduction-related melts and nephelinitic/melilititic melts emplaced in intraplate tectonic settings. The enrichment in Th, coupled with high Ba/Nb and La/Nb, troughs at Ti in primitive mantle-normalised patterns, radiogenic 87Sr/86Sr and positive 7/4 anomalies (from +15.2 to +17.0) are consistent with the presence of (old) recycled crustal lithologies in the sources.The origin of Nowbaran magmas cannot be related to partial melting of C-H-free peridotitic mantle, nor to digestion of limestones and marls by “normal” basaltic melts. Rather, we favour an origin from carbonated lithologies. Carbonated eclogite-derived melts or supercritical fluids, derived from a subducted slab, reacting with peridotite matrix, could have produced peritectic orthopyroxene- and garnet-rich metasomes at the expenses of mantle olivine and clinopyroxene. The residual melt compositions could evolve towards SiO2-undersaturated, CaO- and MgO-rich and Al2O3-poor alkaline melts. During their percolation upwards, these melts can partially freeze reacting chromatographically with portions of the upper mantle wedge, but can also mix with melts from shallower carbonated peridotite. The T-P equilibration estimates for Nowbaran magmas based on recent models on ultrabasic melt compositions are compatible with provenance from the lithosphere-asthenosphere boundary at average temperature (~1200 °C ± 50 °C). Mixing of melts derived from subduction-modified mantle sources with liquids devoid of any subduction imprint, passively upwelling from slab break-off tears could generate magmas with compositions recorded in Nowbaran.

Published
2021

2. Mineralogy and geochemistry of a giant agpaitic magma reservoir: The Late Cretaceous Poços de Caldas potassic alkaline complex (SE Brazil)

Author

Guarino V.[1], Lustrino M.[2, Zanetti A.[4], Tassinari C.C.G.[5], Ruberti E.[5], de' Gennaro R.[1], Melluso L.[1], Guarino, V., Lustrino, M., Zanetti, A., Tassinari, C. C. G., Ruberti, E., de' Gennaro, R., and Melluso, L.

Subjects
Agpaitic, Brazil, Eudialyte, F-disilicates, Nepheline syenites, Phonolite, Poços de Caldas, Titanite, 010504 meteorology & atmospheric sciences, Outcrop, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Peralkaline rock, chemistry.chemical_compound, agpaitic: titanite: eudialyte: F-disilicates: phonolite: nepheline syenites, Poços de Caldas: Brazil, Geochemistry and Petrology, Nepheline, 0105 earth and related environmental sciences, Poços de Calda, geography, geography.geographical_feature_category, Fractional crystallization (geology), F-disilicate, Nepheline syenite, Geology, Massif, Cretaceous, Igneous rock, chemistry, Magma, CRISTALIZAÇÃO
Abstract

The Late Cretaceous (~78 Ma) Poços de Caldas massif is the largest alkaline complex in Brazil and the second in the world by extension (>800 km2). It is considered the westernmost outcrop of the Cabo Frio magmatic lineament, in the northern sector of Serra do Mar potassic-ultrapotassic igneous province, central-eastern Brazil. The outcropping rocks are peralkaline phonolites (~80%) and nepheline syenites (~15%) with rarer (

Published
2021

3. The pyroclastic breccias from Cabezo Negro de Tallante (SE Spain). Is there any relation with carbonatitic magmatism?

Author

Innocenzi F.[1], Ronca S.[1], Agostini S.[2], Brandano M.[1], Caracausi A.[3], and Lustrino M.[1

Subjects
Incompatible element, 010504 meteorology & atmospheric sciences, Carbonate, Lava, basaltic rocks, Calcrete, Carbonatite, petrology, subduction, Geochemistry, Pyroclastic rock, 010502 geochemistry & geophysics, 01 natural sciences, chemistry.chemical_compound, Geochemistry and Petrology, Breccia, Xenolith, 0105 earth and related environmental sciences, Basalt, Geology, chemistry, carbonatite, carbonate, calcrete, Scoria
Abstract

The small Plio-Quaternary volcanic centre of Cabezo Negro de Tallante in SE Spain includes a thick deposit of polymictic pyroclastic tuff-breccia, whose fragments are agglutinated by a carbonate-rich component. This feature is also observed in other monogenetic volcanic centres cropping out in the Tallante-Cartagena volcanic district. The carbonate fraction has been recently interpreted in literature as representing a mantle component, therefore pointing to the existence of a diffuse carbonatitic activity in the area. Based on detailed sedimentological (presence of pisoids and root remnants), petrographic (presence of plagioclase and absence of euhedral silicate minerals in the calcite plagues), mineral chemistry (Ba-Sr-poor calcite composition), whole-rock chemistry (overall low incompatible element content in the pure carbonate fraction and a monotonous trace element negative correlation with CaO) as well as isotopic constraints (perfect correlations between Sr-Nd-Pb isotopic ratios with CaO in the basaltic and carbonate fraction, as well as heavy δ18O and light δ13C isotopic composition of the carbonate fraction), we propose a secondary origin for the carbonate component, excluding any contribution of mantle carbonatite melts. The presence of carbonates infiltrating the abundant mantle and crustal xenolith fragments found in the pyroclastic breccia is not related to the presence of carbonatitic melts at mantle to lower crustal depths, but to in-situ fragmentation of the Strombolian tuff-breccia deposit, followed by secondary carbonate infiltration. The pyroclastic breccia was indeed affected by an alternation of carbonate precipitation and dissolution in a vadose zone, where the activity of bacteria, fungi, roots and meteoric water led to the formation of a calcrete (caliche)-type deposits. Basaltic rocks (hawaiites and basanites) occur in the area as scoria and lava fragments in the pyroclastic breccia as well as small lava flows. They have been modelled with a low-degree partial melting of an amphibole-bearing peridotitic mantle close to the lithosphere-asthenosphere boundary. The origin of the mildly alkaline sodic basaltic activity in SE Spain post-dates the abundant and long-lasting subduction-related volcanic phase in the Betic Chain. Its origin is explained without requiring the presence of any thermal anomaly, but simply as consequence of the difference of lithospheric depths and edge-driven-type small-scale convection.

Published
2021

4. Petrological characterization of the Cenozoic igneous rocks of the Tafresh area, central Urumieh-Dokhtar Magmatic Arc (Iran)

Author

Salari G.[1], Lustrino M.[1, Ghorbani M.R.[3], Agostini S.[4], Fedele L.[5], Salari, Giulia, Lustrino, Michele, Ghorbani, Mohammad Reza, Agostini, Samuele, and Fedele, Lorenzo

Subjects
adakites, Urumieh-Dokhtar, Zagros, subduction-related magmatism, calcalkaline series, Zagro, calcalkaline serie
Abstract

We report a petrographic and whole-rock geochemical characterization of the Cenozoic volcanic rocks cropping out in the Tafresh area of the central Urumieh-Dokhtar Magmatic Arc of Iran. The investigated rocks range mainly from basaltic andesite to dacite, and are considered to be genetically linked by (mostly) closed-system evolutionary processes involving fractionation of ferromagnesian minerals and plagioclase first, then of plagioclase and lesser amphibole (plus minor clinopyroxene) and finally of plagioclase with lesser alkali feldspar and minor amphibole. These represent a typical calcalkaline series emplaced in a subduction-related setting, producing the observed LILE-enriched and HFSE-depleted geochemical signature. The basaltic andesite compositions likely derived from an unsampled hydrous primitive melt equilibrated in a spinel-bearing metasomatized peridotite source, evolving at shallow to moderate crustal depths., Periodico di Mineralogia, Vol. 90 No. 1 (2021)

Published
2021

6. Petrological evolution of Karlıova-Varto volcanism (Eastern Turkey). Magma genesis in a transtensional triple-junction tectonic setting

Author

Karaoglu O.[1], Gülmez F.[2], Göçmengil G.[3], Lustrino M.[4, Di Giuseppe P.[6, Manetti P.[8], Savasçin M.Y.[9], and Agostini S.[6]

Subjects
010504 meteorology & atmospheric sciences, Lava, Alkali basalt, Geochemistry, Pyroclastic rock, Volcanism, asthenospheric mantle source, collision, Eastern Turkey, lithosphere, triple-junction, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, Triple-junction, Collision, Lithosphere, Asthenospheric mantle source, 0105 earth and related environmental sciences, Basalt, geography, Fractional crystallization (geology), geography.geographical_feature_category, Partial melting, Geology, Volcanic rock, 13. Climate action
Abstract

A diffuse and voluminous (>1400 km3) Miocene-Quaternary volcanic activity developed around the KarlıovaTriple Junctionin East Anatolia as a consequence of collisional tectonics among Anatolia, Arabia andEurasiacontinental plates. The volcanic rocks of this region are grouped into three phases of activity: 1) Early Phase (Solhanvolcanism; ~7.3–4.4 Ma), with emplacement ofalkali basaltto trachytelava flowsand pyroclastic successions; 2) Middle Phase (Turnadağ and Vartovolcanism; ~3.6–2.6 Ma), mostly with products with the same compositional range plus minordacitesandrhyolites, and 3) Late Phase (Özenç volcanism; ~2.6–0.5 Ma), with emplacement of alkali basaltic, hawaiitic and mugearitic lavas and dykes. Primitive Mantle-normalized patterns of the three rock groups share an enrichedLILEand depleted HFSE contents, with overall positive spikes of Pb and mildly fractionated LREE/HREE trends showing more similar affinity to global subducting sediments rather than tomagmasemplaced in mid-plate settings (i.e., OIB). Initial Srisotopic ratiosof the least evolved compositions range from values lower than BSE (87Sr/86Sri = 0.7041) to radiogenic compositions (87Sr/86Sri = 0.7050). They reflect either FC-like processes, with87Sr/86Sriup to 0.7064, or closed systemfractional crystallization, with87Sr/86Sri = 0.7046–0.7049. Initial Nd are higher than ChUR estimate for the most and the least evolved compositions (143Nd/144Ndi = 0.51267–0.51280), indicating provenance from isotopically depleted sources. Leadisotopic ratiosare characterized by a remarkable homogeneous206Pb/204Pb (18.95–19.04), with207Pb/204Pb (15.65–15.72) and208Pb/204Pb (38.87–39.21) slightly above the Northern Hemisphere Reference Line, pointing towards the EMII end-member. Geochemical modelling for the least evolved volcanic units indicate the likely generation from an amphibole-bearing spinel-lherzolitic source. P-T calculations for partial melting calculations gave lithospheric pressures for initialmagma generation(0.8–1.3 GPa). Possible cause of melting might be related to passive upwelling ofasthenosphereas a response to the local extension linked to the development of North Anatolian and East Anatolian Fault Zones. Anyhow, volcanic units from the KTJ display only limited geochemical signatures of garnet-bearing sources, or any HIMU-OIB like characteristics, as instead observed in the other portions of the Eastern Anatolia. The long-lasting complextectonic evolutionof the Eastern Anatolia is responsible for the large geochemical variability of the magmatic products. However, the general characteristics of KTJ volcanic rocks are mainly dominated by subduction-related signatures, with most of the primary magma characteristics having been heavily masked by fractionation and crustal assimilation processes.

Published
2020

7. Neogene volcanism in Elazig-Tunceli area (eastern Anatolia): geochronological and petrological constraints

Author

Agostini S.[1], Savascin M.[2], Di Giuseppe P.[1, Di Stefano F.[4], Karaoglu O.[5], Lustrino M.[4, Manetti P.[7, Ersoy Y.[8], Kürüm S.[9], and Önal A.[2]

Subjects
Eastern Anatolia, radiogenic isotopes, Ar-Ar geochronology, petrology, Neogene volcanism
Abstract

The Elaz?? and Tunceli provinces in eastern Anatolia host a complex succession of Miocene-Pleistocene effusive and explosive volcanic rocks, divided into four distinct volcanic phases. The most abundant and widespread products are the calcalkaline Mazgirt volcanic rocks, characterized by wide Sr isotope variations (87Sr/86Sr ~0.7054-0.7077) and narrower 143Nd/144Nd (~0.51246-0.51260) and Pb isotopes (e.g., 206Pb/204Pb ~18.89-19.13). New 40Ar-39Ar ages indicate that Mazgirt volcanic activity occurred between ~16.3 and 15.1 Ma. The other three volcanic phases are represented by the Tunceli mildly alkaline basaltic lavas (~11.4-11.0 Ma), the Pliocene Karakoçan (~4.1 Ma) and Pleistocene Elaz?? (~1.9-1.6 Ma) Na-alkali basaltic lavas with clear OIB-like geochemical signature. Mazgirt volcanics can be subdivided on the base of mode of emplacement into lava flows and lava domes units characterized by petrographic, chemical and isotopic differences: lava flows are calcalkaline, whereas lava domes mostly belong to a high-K calcalkaline series and are, on average, more LREE- and 87Sr-enriched. Lava domes are more porphyritic, with a phenocryst assemblage dominated by amphibole, whereas plagioclase and clinopyroxene are the most abundant phenocryst phases in lava flows, pointing out that evolution of dome magmas occurred in conditions of slightly higher pressure, favouring the crystallization of hydrous phases. The Karabak?r Formation, previously reported as late Miocene- Pliocene, encloses Mazgirt volcanics and is capped by Tunceli basalts. These new age data constrain the Karabak?r Formation emplacement from early to late Miocene. The evolution of this igneous activity mirrors the geodynamic framework of the region: the early-middle Miocene Mazgirt volcanics represent arc volcanism related to Eurasia-Arabia convergence. The late Miocene Tunceli basalts postdate the onset of post-collisional tectonics in Eastern Anatolia, whereas the Karakoçan and Elaz?? volcanic rocks were emplaced after the initiation of strike-slip motion on the North Anatolian and East Anatolian Fault systems.

Published
2019

12. Preface

Author

Foulger, G. R., Lustrino, M., and King, S. D.

Published
2015

13. The mantle isotopic printer: Basic mantle plume geochemistry for seismologists and geodynamicists

Author

Lustrino M. and Anderson D.L.

Subjects
mantle plume geochemistry
Abstract

High-temperature geochemistry combined with igneous petrology is an essential tool to infer the conditions of magma generation and evolution in the Earth's interior. During the past thirty years, a large number of geochemical models of the Earth, essentially inferred from the isotopic composition of basaltic rocks, have been proposed. These geochemical models have paid little attention to basic physics concepts, broadband seismology, or geological evidence, with the effect of producing results that are constrained more by assumptions than by data or first principles. This may not be evident to seismologists and geodynamicists. A common view in igneous petrology, seismology, and mantle modeling is that isotope geochemistry (e.g., the Rb-Sr, Sm-Nd, U-Th-Pb, U-Th-He, Re-Os, Lu-Hf, and other less commonly used systems) has the power to identify physical regions in the mantle, their depths, their rheological behavior, and the thermal conditions of magma generation. We demonstrate the fallacy of this approach and the model-dependent conclusions that emerge from unconstrained or poorly constrained geochemical models that do not consider physics, seismology (other than teleseismic travel-time tomography and particularly compelling colored mantle cross sections), and geology. Our view may be compared with computer printers. These can reproduce the entire range of colors using a limited number of basic colors (black, magenta, yellow, and cyan). Similarly, the isotopic composition of oceanic basalts and nearly all their primitive continental counterparts can be expressed in terms of a few mantle end members. The four most important (actually "most extreme", because some are extraordinarily rare) mantle end members identified by isotope geochemists are DMM or DUM (depleted MORB [mid-ocean-ridge basalt] mantle or depleted upper mantle), HIMU (high mu, where mu = ?= 238U/204Pb), EMI, and EMII (enriched mantle type I and type II). Other mantle end members, or components, have been proposed in the geochemical literature (e.g., PHeM, FOZO, LVC, PreMa, EMIII, CMR, LOMU, and C), but these can be considered to be less extreme components or mixtures in the geochemical mantle zoo. Assuming the existence of these extreme "colors" in the mantle isotopic printer, the only matter for debate is their location in the Earth's interior. At least three of them need long-term insulation from convection-driven homogenization or mixing processes. In other words, where these extreme isotopic end members are located needs to be defined. In our view, no geochemical, geological, geophysical, or physical arguments require the derivation of any magma from deep mantle sources. Arguments to the contrary are assumption based. The HIMU, EMI, and EMII end members can be entirely located in the shallow non-convecting volume of the mantle, while the fourth, which is by far the more abundant volumetrically (DMM or DUM), can reside in the transition zone. This view is inverted compared with current canonical geochemical views of the Earth's mantle, where the shallowest portions are assumed to be DMM like (ambient mantle) and the EMI-EMII-HIMU end members are assumed to be isolated, located in the deep mantle, and associated with thermal anomalies. We argue that the ancient, depleted signatures of DMM imply long-term isolation from recycling and crustal contamination while the enriched components are not free of contamination by shallow materials and can therefore be shallow.

Published
2015

14. From Lesotho basaltic highlands to the Namib Sand Sea: long-distance transport and compositional variability in the wind-displaced Orange Delta

Author

GARZANTI, EDUARDO, ANDO', SERGIO, VEZZOLI, GIOVANNI, Vermeesch, P, Boni, M, Lustrino, M, Garzanti, E, Vermeesch, P, Ando', S, Boni, M, Lustrino, M, and Vezzoli, G

Subjects
Sand, Provenance, Africa, Nile, Orange
Abstract

Sourced as the Nile in distant basaltic rift highlands, the Orange River is the predominant ultimate source of sand for the Namib desert dunes, as proved independently by bulk-petrography, heavy-mineral, pyroxene-chemistry, and U/Pb zircon-age datasets. Additional local entry points of sand do exist at the edges of the desert, and were quantified by comparison with detrital modes and heavy-mineral suites of hinterland-river sediments. After long-distance fluvial transport, Orange sand is washed by ocean waves and dragged northward by vigorous longshore currents. Under the incessant action of southerly winds, sand is blown inland and carried farther north to accumulate in the Namib erg, a peculiar wind-dominated sediment sink displaced hundreds of kilometres away from the river mouth. And yet changes in sand mineralogy along the way are minor. After a multistep journey of cumulative 3000 km from their source in Lesotho, volcanic rock fragments and pyroxene are found in unchanged abundance as far as the northern edge of the desert. Only locally is volcanic detritus slightly depleted and minor but regular enrichment in quartz and garnet observed, the sole potential effect of prolonged transport or recycling of Tertiary eolianites. Selective comminution of fragile minerals is thus proved unable to substantially modify sand composition in fluvial, coastal, or eolian settings. Mechanical processes have a much greater effect on the morphology of detrital grains, which in Namib dunes appear commonly shaped into nearly perfect spheres. Eolian sorting concentrates denser minerals locally in placer lags, but such effects can be identified and compensated for. This study demonstrates that mechanical breakdown is unable to markedly affect provenance signatures even during long-distance and prolonged multistep transport in high-energy settings. In arid climates, where chemical processes are negligible, high-resolution bulk-petrography and heavy-mineral analyses are thus powerful techniques to quantitatively reconstruct provenance, and to trace sediment sources and dispersal paths over distances up to thousands of kilometres.

Published
2012

15. Petrogenesis of a basalt-comendite-pantellerite rock suite: the Boseti volcanic complex, Main Ethiopian Rift

Author

Ronga F.[1], Lustrino M.[2, Marzoli A.[4], Melluso L.[1], Ronga, F., Lustrino, M., Marzoli, A., and Melluso, Leone

Subjects
Basalt, Fractional crystallization (geology), peralkaline, pantellerite, magma, Anorthoclase, Geochemistry, Silicic, Magma chamber, rhyolite, engineering.material, Peralkaline rock, Geophysics, Boseti Volcanic complex, Geochemistry and Petrology, Main Ethiopian Rift, continental rift, engineering, alkaline, Mafic, Boseti Volcanic Complex (Main Ethiopian Rift), Geology, petrogenesi, Petrogenesis
Abstract

Petrological and geochemical data for basic (alkali basalts and hawaiites) and silicic peralkaline rocks, plus rare intermediate products (mugearites and benmoreites) from the Pleistocene Boseti volcanic complex (Main Ethiopian Rift, East Africa) are reported in this work. The basalts are slightly alkaline or transitional, have peaks at Ba and Nb in the mantle-normalized diagrams and relatively low 87Sr/86Sr (0.7039-0.7044). The silicic rocks (pantellerites and comendites) are rich in sanidine and anorthoclase, with mafic phases being represented by fayalite-rich olivine, opaque oxides, aenigmatite and slightly Na-rich ferroaugite (ferrohedenbergite). These rocks were generated after prolonged fractional crystallization process (up to 90-95 %) starting from basaltic parent magmas at shallow depths and fO2 conditions near the QFM buffer. The apparent Daly Gap between mafic and evolved Boseti rocks is explained with a model involving the silicic products filling upper crustal magma chambers and erupted preferentially with respect to basic and intermediate products. Evolved liquids could have been the only magmas which filled the uppermost magma reservoirs in the crust, thus giving time to evolve towards Rb-, Zr- and Nb-rich peralkaline rhyolites in broadly closed systems.

Published
2010

16. The beginning of the Apennine subduction system in central-western Mediterranean: constraints from Cenozoic 'orogenic' magmatic activity of Sardinia (Italy)

Author

Lustrino M., MORRA, VINCENZO, FEDELE, LORENZO, FRANCIOSI, LUIGI, Lustrino, M., Morra, Vincenzo, Fedele, Lorenzo, and Franciosi, Luigi

Abstract

Major and trace element analyses plus six new (40)Ar/(39)Ar data obtained on feldspar separates for selected igneous rocks belonging to the Oligo-Miocene igneous activity of Sardinia are reported here. The rocks show "subduction-related'' geochemical characteristics, ascribed to the metasomatic modification of a mantle wedge developed above a W/NW directed subduction system involving the recycling of Neo-Tethyan oceanic lithosphere beneath the southern European margin. The (40)Ar/(39)Ar data shift back the beginning of the igneous activity in Sardinia to late Eocene (38.28 +/- 0.26 Ma), whereas the end of the igneous activity is possibly shifted forward to late middle Miocene (12.24 +/- 0.98 Ma). We therefore propose to rename the Oligo-Miocene igneous phase as the "late Eocene-middle Miocene'' phase. Rare earth element inversion modeling on subduction-related volcanic rocks of Sardinia requires equilibrium with spinellherzolite facies, therefore implying depths of formation lower than similar to 80 km. To reach these depths, a 45 degrees dipping slab needs similar to 11 to similar to 4 Myr (with 1 to 3 cm/yr subduction velocity, respectively), reducing the beginning of Apennine subduction to the similar to 49-42 Ma interval. The different models proposed in literature to explain the origin and the evolution of the central western Mediterranean basins are here reviewed and critically discussed. Citation: Lustrino, M., V. Morra, L. Fedele, and L. Franciosi (2009), Beginning of the Apennine subduction system in central western Mediterranean: Constraints from Cenozoic "orogenic'' magmatic activity of Sardinia, Italy.

Published
2009

18. Alpine Tethys closure as revealed by amphibole-rich mafic and ultramafic rocks from the Adamello and the Bergell intrusions (Central Alps)

Author

Tiepolo M.[1], Tribuzio R.[1, Ji W.[3], Wu F.[3], and Lustrino M. [4

Subjects
Adamello, Bergell pluton, Gabbro, Pluton, amphibole gabbro, Alps, Geochemistry, Geology, zircon, Diorite, Adamello batholith, Batholith, Ultramafic rock, Alps, hornblendite, gabbro, tectonics, subduction, geodynamics, zircon, Hf isotopes, Adamello, Hf isotopes, tectonics, geodynamics, Mafic, hornblendite, Petrology, subduction, Amphibole, Zircon, gabbro
Abstract

U–Pb ages and Hf isotope data were obtained for zircon from amphibole-rich mafic to ultramafic rocks from the Adamello batholith and the Bergell pluton, the largest Palaeogene intrusions of the Alpine Orogen. The 206 Pb/ 238 U age pattern of U–Pb concordant dates from the Adamello mafic rock shows a major crystallization event at c . 41 Ma and older age peaks at c . 50 and c . 45 Ma. Hornblendite and amphibole gabbro samples of the Adamello batholith have zircon with initial ϵHf of c . +9.0 and c . +7.0, respectively. Amphibole gabbro and diorite samples of the Bergell pluton yield a younger age of c . 31 Ma and have zircon with lower initial ϵHf ( c . +4.0). We propose that the amphibole-rich rocks from the Adamello batholith originated from a depleted mantle source activated by the subduction of the Ligurian–Piedmontese Basin. The amphibole-rich rocks from the Bergell pluton formed 10–15 Ma later than the Adamello counterparts by melts derived from a mantle sector metasomatized by the subduction of the Valais Basin. The enriched Hf isotopic signature of the amphibole-rich rocks from the Bergell pluton is therefore interpreted to reflect the peculiar lithostratigraphy of the Valais Basin or a primary feature of the newly activated mantle source. Supplementary material: (1) A map showing the location of analysed samples and table with GPS coordinates of the samples, (2) data tables for U–Pb in zircon determined by LA-ICP-MS, (3) data tables for Hf isotopes in zircon, (4) U–Pb and Hf isotope analytical methods, (5) cathodoluminescence images of analysed zircon from the amphibole-rich mafic rocks of the Adamello and Bergell intrusions, and (6) a U–Pb concordia diagram for zircon of the Adamello amphibole gabbro are available at www.geolsoc.org.uk/SUP18763.

Published
2014

25. Plio-Pleistocene igneous activity in Sardinia

Author

PETTERUTI LIEBERKNECHT A. M, FEDELE, LORENZO, DAMELIO F, LUSTRINO M, MELLUSO L, MORRA, VINCENZO, PETTERUTI LIEBERKNECHT A., M, Fedele, Lorenzo, Damelio, F, Lustrino, M, Melluso, L, and Morra, Vincenzo

Published
2003

32. Heterogeneous mantle sources feeding the volcanic activity of Mt. Karacada? (SE Turkey)

Author

Lustrino M.(a, Keskin M.(c), Mattioli M.(d), and Kavak O.(e)

Subjects
Basalt, geography, Incompatible element, arabia, geography.geographical_feature_category, Turkey, Partial melting, Geochemistry, Geology, Solidus, Mantle (geology), Volcanic rock, petrology, anatolia, mantle, turkey, basalt, geochemistry, Anatolia, Mafic, Mantle, Turkey Anatolia Basalt Petrology Mantle Geochemistry Arabia, Amphibole, Earth-Surface Processes, Petrology
Abstract

The volcanic activity of Mt. Karacadag (SE Anatolia) is divided into three major stages: Siverek Stage (∼11–2.7 Ma), Karacadag Stage (∼1.9–1.0 Ma) and Ovabag Stage (0.4–0.01 Ma). The magmas are mildly alkaline mafic rocks, mostly basanites, hawaiites and alkali basalts. Detailed geochemical investigation indicates a continuous variation of composition with time, with the oldest products (Siverek Stage) being characterized by average lowest HFSE (Ti, Hf, Zr, Nb, Ta), 143Nd/144Nd, Nb/U, Ta/Yb, Nb/Nb* and the highest ΔQ, La/Nb, Ti/Nb, Zr/Nb, Ba/Nb, Th/Ta, K/La, and the youngest products (Ovabag Stage) at the opposite end of the trend. The overall incompatible element content of the Karacadag volcanic rocks resembles closely average HIMU-OIB compositions, with the oldest samples deviating more strongly from typical compositions of “anorogenic” magmas. We interpret these geochemical variations with a process of partial melting of a chemically and mineralogically heterogeneous mantle source rather than with process of variable crustal contamination at shallow depths. During the first stages of mantle melting the volumes with lowest solidus temperature (e.g., the amphibole and phlogopite-rich metasomes, particularly abundant in the Arabia mantle xenolith suite) contributed significantly to the partial melts. “Average” peridotitic matrix is involved in partial melting processes only when these metasomatic volumes start to be exhausted, producing mantle melts with geochemical composition resembling average “anorogenic” mildly alkaline sodic rocks, common in the circum-Mediterranean area.

Published
2012

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