Eruptive history and petrologic evolution of the Albano multiple maar (Alban Hills, Central Italy)     

Carmela Freda  Mario Gaeta  Daniel B. Karner  Fabrizio Marra  Paul R. Renne  Jacopo Taddeucci  Piergiorgio Scarlato  John N. Christensen  Luigi Dallai 《Bulletin of Volcanology》2006,68(6):567-591

A comprehensive volcanological study of the Albano multiple maar (Alban Hills, Italy) using (i) ⁴⁰Ar/³⁹Ar geochronology of the most complete stratigraphic section and other proximal and distal outcrops and (ii) petrographic observations, phase analyses of major and trace elements, and Sr and O isotopic analyses of the pyroclastic deposits shows that volcanic activity at Albano was strongly discontinuous, with a first eruptive cycle at 69±1 ka producing at least two eruptions, and a second cycle with two peaks at 39±1 and 36±1 ka producing at least four eruptions. Contrary to previous studies, we did not find evidence of magmatic or hydromagmatic eruptions younger than 36±1 ka. The activity of Albano was fed by a new batch of primary magma compositionally different from that of the older activity of the Alban Hills; moreover, the REE and ⁸⁷Sr/⁸⁶Sr data indicate that the Albano magma originated from an enriched metasomatized mantle. According to the modeled liquid line of descent, this magma differentiated under the influence of magma/limestone wall rock interaction. Our detailed eruptive and petrologic reconstruction of the Albano Maar evolution substantiates the dormant state of the Alban Hills Volcanic District. Electronic Supplementary Material Supplementary material is available for this article at Editorial responsibility: J. Donnelly-Nolan An erratum to this article can be found at  相似文献   

A note on maar eruption energetics: current models and their application   总被引：1，自引：1，他引：0  

Jacopo Taddeucci  Gianluca Sottili  Danilo M. Palladino  Guido Ventura  Piergiorgio Scarlato 《Bulletin of Volcanology》2010,72(1):75-83

Hydromagmatic eruptions convert thermal into mechanical energy via the expansion of ground- and/or surface-water. Several models address the energetics of these eruptions based on different physical-volcanological approaches. Here we test different models with two case studies in the Colli Albani Volcanic District (central Italy): the monogenetic Prata Porci and the polygenetic Albano maars. Test results are mutually consistent, and show cumulative mechanical energy releases on the order of 10¹⁵–10¹⁷ J for single maars. The fraction of thermal energy turned into mechanical ranges from 0.45 (as calculated from the theoretical maximum mechanical energy), through 0.1 (calculated from country rock fragmentation, crater formation and ballistic ejection), to 0.03 (derived from magma fragmentation by thermohydraulic explosions). It appears that the energy released during the most intense hydromagmatic events may account for a dominant fraction of the total mechanical energy released during the whole maar eruptive histories. Finally, we consider the role of magmatic explosive activity intervening during maar eruptions in causing departures from predictions of the models evaluated.  相似文献   

The control of cooling rate on titanomagnetite composition: implications for a geospeedometry model applicable to alkaline rocks from Mt. Etna volcano     

Silvio Mollo  Keith Putirka  Gianluca Iezzi  Piergiorgio Scarlato 《Contributions to Mineralogy and Petrology》2013,165(3):457-475

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CO<Subscript>2</Subscript>-driven large mafic explosive eruptions: the Pozzolane Rosse case study from the Colli Albani Volcanic District (Italy)     

Carmela Freda  Mario Gaeta  Biagio Giaccio  Fabrizio Marra  Danilo M. Palladino  Piergiorgio Scarlato  Gianluca Sottili 《Bulletin of Volcanology》2011,73(3):241-256

Generally, the intensity and magnitude of explosive volcanic activity increase in parallel with SiO₂ content. Pyroclastic-flow-forming eruptions in the Colli Albani ultrapotassic volcanic district (Italy) represent the most striking exception on a global scale, with volumes on the order of tens of cubic kilometres and K-foiditic compositions (SiO₂ even <42 wt.%). Here, we reconstruct the pre-eruptive scenario and event dynamics of the ~456 ka Pozzolane Rosse (PR) eruption, the largest mafic explosive event of the Colli Albani district. In particular, we focus on the driving mechanisms for the unusually explosive eruption of a low-viscosity, mafic magma. Geologic, petrographic and geochemical data with mass balance calculations, supported by experimental data for Colli Albani magma compositions, provide evidence for significant ingestion of carbonate wall rocks by the Pozzolane Rosse K-foiditic magma. Moreover, the scattered occurrence of cored bombs in Pozzolane Rosse pyroclastic-flow deposits records carbonate entrainment even at the eruptive time scale, as also tested quantitatively by thermal modelling of magma–carbonate interaction and carbonate assimilation experiments. We suggest that the addition of free CO₂ from decarbonation of country rocks was the major factor controlling magma explosivity. High CO₂ activity in the volatile component, coupled with magma depressurisation, produced extensive leucite crystallisation at short time scales, resulting in a dramatic increase in magma viscosity and volatile pressurisation, which was manifested a change of eruptive dynamics from early effusion to the Pozzolane Rosse's highly explosive eruption climax.  相似文献   

Recycled ejecta modulating Strombolian explosions     

Antonio Capponi  Jacopo Taddeucci  Piergiorgio Scarlato  Danilo M. Palladino 《Bulletin of Volcanology》2016,78(2):13

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Eruptive history and petrologic evolution of the Albano multiple maar (Alban Hills, Central Italy)     

Carmela Freda  Mario Gaeta  Daniel B. Karner  Fabrizio Marra  Paul R. Renne  Jacopo Taddeucci  Piergiorgio Scarlato  John N. Christensen  Luigi Dallai 《Bulletin of Volcanology》2006,69(1):115-115

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Modelling flood events with a cumulant CO lattice Boltzmann shallow water model     

Venturi  Sara  Di Francesco  Silvia  Geier  Martin  Manciola  Piergiorgio 《Natural Hazards》2021,105(2):1815-1834

Natural Hazards - In this work the development of a semiautomatic procedure based on the coupled use of a GIS subroutine and a two-dimensional hydraulic lattice Boltzmann model solving the shallow...  相似文献   

Contrasting radon background levels in volcanic settings: clues from 220Rn activity concentrations measured during long-term deformation experiments     

Piergiorgio Scarlato  Paola Tuccimei  Silvio Mollo  Michele Soligo  Mauro Castelluccio 《Bulletin of Volcanology》2013,75(9):1-8

To better understand the mechanisms leading to different radon background levels in volcanic settings, we have performed two long-term deformation experiments of 16 days using a real-time setup that enables us to monitor any variation of radon activity concentration during rock compression. Our measurements demonstrate that, in the case of highly porous volcanic rocks, the emanating power of the substrate changes as a function of the volcanic stress conditions. Constant magmatic pressures, such as those observed during dike intrusions and hydrothermal fluid injections, can result in pervasive pore collapse that is mirrored by a significant radon decrease until a constant emanation is achieved. Conversely, repeated cycles of stress due to, for example, volcano inflation/deflation cycles, cause a progressive radon increase a few days (but even weeks and months) before rupture. After rock failure, however, the formation of new emanation surfaces leads to a substantial increase of the radon signal. Our results suggest that surface deformation in tectonic and volcanic settings, such as inflation/deflation or constant magmatic pressures, have important repercussions on the emanating power of volcanic substrates.  相似文献   

Surfaces and atmospheres of the outer planets, their satellites and ring systems: Part IV     

Athena Coustenis  Sushil Atreya  Piergiorgio Casavecchia  Julie Castillo  Odile Dutuit  Hauke Hussmann  Frank Sohl 《Planetary and Space Science》2008,56(12):1571-1572

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Carbonate assimilation in magmas: A reappraisal based on experimental petrology     

Silvio Mollo  Mario Gaeta  Carmela Freda  Tommaso Di Rocco  Valeria Misiti  Piergiorgio Scarlato 《Lithos》2010,114(3-4):503-514

The main effect of magma–carbonate interaction on magma differentiation is the formation of a silica-undersaturated, alkali-rich residual melt. Such a desilication process was explained as the progressive dissolution of CaCO₃ in melt by consumption of SiO₂ and MgO to form diopside sensu stricto. Magma chambers emplaced in carbonate substrata, however, are generally associated with magmatic skarns containing clinopyroxene with a high Ca-Tschermak activity in their paragenesis. Data are presented from magma–carbonate interaction experiments, demonstrating that carbonate assimilation is a complex process involving more components than so far assumed. Experimental results show that, during carbonate assimilation, a diopside–hedenbergite–Ca-Tschermak clinopyroxene solid solution is formed and that Ca-Tschermak/diopside and hedenbergite/diopside ratios increase as a function of the progressive carbonate assimilation. Accordingly, carbonate assimilation reaction should be written as follows, taking into account all the involved magmatic components:CaCO₃^solid + SiO₂^melt + MgO^melt + FeO^melt + Al₂O₃^melt → (Di–Hd–CaTs)_ss^solid + CO₂^fluidThe texture of experimental products demonstrates that carbonate assimilation produces three-phases (solid, melt, and fluid) whose main products are: i) diopside–hedenbergite–Ca-Tschermak clinopyroxene solid solution; ii) silica-undersaturated CaO-rich melt; and iii) C–O–H fluid phase. The silica undersaturation of the melt and, more importantly, the occurrence of a CO₂-rich fluid phase, must be taken into account as they significantly affect partition coefficients and the redox state of carbonated systems, respectively.  相似文献