Your search keyword '"Matteo Trolese"' showing total 6 results

1. Calibrating Carbonization Temperatures of Wood Fragments Embedded within Pyroclastic Density Currents through Raman Spectroscopy

Author

Andrea Schito, Alessandra Pensa, Claudia Romano, Sveva Corrado, Alessandro Vona, Matteo Trolese, Daniele Morgavi, Guido Giordano, Schito, Andrea, Pensa, Alessandra, Romano, Claudia, Corrado, Sveva, Vona, Alessandro, Trolese, Matteo, Morgavi, Daniele, and Giordano, Guido

Subjects

pyroclastic density current, charcoal, Raman spectroscopy, pyroclastic density currents, charcoal reflectance, multivariate polynomial regression, Geology, Geotechnical Engineering and Engineering Geology

Abstract

The study of the structural order of charcoals embedded in pyroclastic density currents provides information on their emplacement temperature during volcanic eruptions. In the present work, a set of charcoals from three distinct pyroclastic density currents deposits whose temperatures have been previously estimated by charcoal reflectance analyses to lie between 250 °C and 550 °C, was studied by means of Raman spectroscopy. The analyses reveal a very disordered structural ordering of the charcoals, similar to kerogen matured under diagenetic conditions. Changes in Raman spectra at increasing temperatures reflect depolymerization and an increase of aromaticity and can be expressed by parameters derived from a simplified fitting method. Based on this approach, a second order polynomial regression with a high degree of correlation and a minimum error was derived to predict paleotemperatures of pyroclastic deposits. Our results show that Raman spectroscopy can provide a reliable and powerful tool for volcanological studies and volcanic hazard assessment given its advantage of minimum samples preparation, rapid acquisition processes and high precision.

Published

2022

2. Reply to Narkiewicz (2017) comment on 'Thermal evolution of Paleozoic successions of the Holy Cross Mountains (Poland)'

Author

Andrea Schito, Bruno Valentim, Domenico Grigo, Luca Aldega, Chiara Caricchi, Simonetta Cirilli, Matteo Trolese, Alexandra Guedes, Sveva Corrado, Amalia Spina, Schito, A., Corrado, S., Trolese, M., Aldega, L., Caricchi, C., Cirilli, S., Grigo, D., Guedes, A., Spina, A., and Valentim, B.

Subjects

010506 paleontology, Holy Cross Mountains, Paleozoic, Stratigraphy, Holy Cross mountains, Paleozoic source rocks, sedimentary basins, thermal modelling, oceanography, geophysics, geology, economic geology, stratigraphy, Fault (geology), 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Paleontology, Sedimentary basins, Thermal, Economic geology, Geophysic, 0105 earth and related environmental sciences, geography, Thermal modelling, Sedimentary basins, Paleozoic source rocks, Holy Cross Mountains, geography.geographical_feature_category, Paleozoic source rock, Geology, Sedimentary basin, Holy Cross Mountain, Geophysics, Thermal modelling, Economic Geology, Heat flow

Abstract

In this paper we reply to the criticisms advanced by Narkiewicz (2017) on the paper by Schito et al. (2017). We clarify the issues related to the stratigraphic and thermal maturity constraints used for reconstructing burial and thermal models of the two blocks of the Holy Cross Mountains. We also show how geological evidences brought by Narkiewicz (2017) as a proof of elevated Variscan heat flow are not conclusive or at least suggest the occurence of a localized thermal anomaly only along the area of the Holy Cross Fault. In the end, we performed new burial and thermal models in the Kielce region demonstrating that stratigraphic thickness variations between Schito et al. (2017) and Narkiewicz et al. (2010) produce only negligible differences in levels of thermal maturity of Paleozoic rocks. In addition, we outline that levels of thermal maturity for Silurian rocks can be matched only by using constant heat flow values through the Paleozoic and point to a decisive role for the absence of regional high Variscan heat flow in the area.

Published

2017

3. A bedform phase diagram for dense granular currents

Author

Guido Giordano, Aurora Silleni, Gregory M. Smith, Samuel Capon, Peter James Rowley, Daniel R. Parsons, Matteo Trolese, Rebecca Williams, Smith, G., Rowley, P., Williams, R., Giordano, G., Trolese, M., Silleni, A., Parsons, D. R., and Capon, S.

Subjects

bepress|Physical Sciences and Mathematics, bepress|Physical Sciences and Mathematics|Earth Sciences|Sedimentology, Volcanic hazards, Bedform, bepress|Physical Sciences and Mathematics|Physics, 010504 meteorology & atmospheric sciences, Outcrop, EarthArXiv|Physical Sciences and Mathematics|Physics|Fluid Dynamics, Science, EarthArXiv|Physical Sciences and Mathematics|Physics, bepress|Physical Sciences and Mathematics|Physics|Fluid Dynamics, bepress|Physical Sciences and Mathematics|Earth Sciences, General Physics and Astronomy, Pyroclastic rock, Volcanology, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, 010502 geochemistry & geophysics, 01 natural sciences, bepress|Physical Sciences and Mathematics|Earth Sciences|Volcanology, General Biochemistry, Genetics and Molecular Biology, Deposition (geology), Article, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Sedimentology, Petrology, lcsh:Science, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Volcanology, 0105 earth and related environmental sciences, Phase diagram, geography, Multidisciplinary, geography.geographical_feature_category, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geology, Turbulence, bepress|Physical Sciences and Mathematics|Earth Sciences|Geology, Natural hazards, General Chemistry, Sedimentology, EarthArXiv|Physical Sciences and Mathematics, Volcano, lcsh:Q, Geology

Abstract

Pyroclastic density currents (PDCs) are a life-threatening volcanic hazard. Our understanding and hazard assessments of these flows rely on interpretations of their deposits. The occurrence of stratified layers, cross-stratification, and bedforms in these deposits has been assumed as indicative of dilute, turbulent, supercritical flows causing traction-dominated deposition. Here we show, through analogue experiments, that a variety of bedforms can be produced by denser, aerated, granular currents, including backset bedforms that are formed in waning flows by an upstream-propagating granular bore. We are able to, for the first time, define phase fields for the formation of bedforms in PDC deposits. We examine how our findings impact the understanding of bedform features in outcrop, using the example of the Pozzolane Rosse ignimbrite of the Colli Albani volcano, Italy, and thus highlight that interpretations of the formative mechanisms of these features observed in the field must be reconsidered., In this study, Smith and colleagues employ analogue experiments to show the controlling parameters on sediment bedforms in pyroclastic density current deposits. The findings are applied and validated on natural deposits.

Published

2019

4. Thermal interactions of the AD79 Vesuvius pyroclastic density currents and their deposits at Villa dei Papiri (Herculaneum archaeological site, Italy)

Author

Elena Zanella, Nobuo Geshi, Alessandro Vona, Chiara Caricchi, Matteo Trolese, C. Baffioni, Sveva Corrado, A. A. De Benedetti, Guido Giordano, Claudia Romano, Roberto Sulpizio, Giordano, G., Zanella, E., Trolese, M., Baffioni, C., Vona, A., Caricchi, C., De Benedetti, A. A., Corrado, S., Romano, C., Sulpizio, R., and Geshi, N.

Subjects

Thermal equilibrium, Paleomagnetism, 010504 meteorology & atmospheric sciences, pyroclastic density current, temperature hazard, Vesuvius, Herculaneum, paleomagnetism, plinian eruption, Pyroclastic rock, 010502 geochemistry & geophysics, 01 natural sciences, Sedimentary depositional environment, Boundary layer, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Remanence, Clastic rock, Convective mixing, Earth and Planetary Sciences (miscellaneous), Petrology, Geology, 0105 earth and related environmental sciences

Abstract

Pyroclastic density currents (PDCs) can have devastating impacts on urban settlements, due to their dynamic pressure and high temperatures. Our degree of understanding of the interplay between these hot currents and the affected infrastructures is thus fundamental not only to implement our strategies for risk reduction, but also to better understand PDC dynamics. We studied the temperature of emplacement of PDC deposits that destroyed and buried the Villa dei Papiri, an aristocratic Roman edifice located just outside the Herculaneum city, during the AD79 plinian eruption of Mt Vesuvius (Italy) by using the thermal remanent magnetization of embedded lithic clasts. The PDC deposits around and inside the Villa show substantial internal thermal disequilibrium. In areas affected by convective mixing with surface water or with collapsed walls, temperatures average at around 270 °C (min 190 °C, max 300 °C). Where the deposits show no evidence of mixing with external material, the temperature is much higher, averaging at 350 °C (min 300 °C; max 440 °C). Numerical simulations and comparison with temperatures retrieved at the very same sites from the reflectance of charcoal fragments indicate that such thermal disequilibrium can be maintained inside the PDC deposit for time-scales well over 24 hours, i.e. the acquisition time of deposit temperatures for common proxies. We reconstructed in detail the history of the progressive destruction and burial of Villa dei Papiri and infer that the rather homogeneous highest deposit temperatures (average 350 °C) were carried by the ash-sized fraction in thermal equilibrium with the fluid phase of the incoming PDCs. These temperatures can be lowered on short time- (less than hours) and length-scales (meters to tens of meters) only where convective mixing with external materials or fluids occurs. By contrast, where the Villa walls remained standing the thermal exchange was only conductive and very slow, i.e. negligible at 50 cm distance from contact after 24 hours. We then argue that the state of conservation of materials buried by PDC deposits largely depends on the style of the thermal interactions. Here we also suggest that PDC deposit temperatures are excellent proxies for the temperatures of basal parts of PDCs close to their depositional boundary layer. This general conclusion stresses the importance of mapping of deposit temperatures for the understanding of thermal processes associated with PDC flow dynamics and during their interaction with the affected environment.

Published

2018

5. Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)

Author

Peter J. Baxter, Jean-Christophe Komorowski, Matteo Trolese, P. Raditya, Guido Giordano, Noer Cholik, Sveva Corrado, Susanna F. Jenkins, Asian School of the Environment, Earth Observatory of Singapore, Trolese, M., Giordano, G., Komorowski, J. -C., Jenkins, S. F., Baxter, P. J., Cholik, N., Raditya, P., and Corrado, S.

Subjects

Volcanic hazards, 010504 meteorology & atmospheric sciences, Geochemistry, Pyroclastic rock, Pyroclastic Density Current, Geology [Science], 010502 geochemistry & geophysics, 01 natural sciences, Matrix (geology), Dome (geology), Geochemistry and Petrology, Emplacement temperature, Charcoal reflectance, Rapid cooling, Charcoal, Geophysic, 0105 earth and related environmental sciences, Explosive eruption, Volcanic hazard, Fragmentation (computing), Merapi Volcano, Geophysics, visual_art, Clastic rock, visual_art.visual_art_medium, Geology

Abstract

Understanding the thermal behavior of pyroclastic density currents (PDCs) is crucial for forecasting impact scenarios for exposed populations as it affects their lethality and destructiveness. Here we report the emplacement temperatures of PDC deposits produced during the paroxysmal explosive eruption of Merapi (Central Java) on 5 November 2010 based on the reflectance of entombed charcoal fragments. This event was anomalously explosive for Merapi, and destroyed the summit dome that had been rapidly growing, with partial collapses and associated PDCs, since October 26. Results show mean reflectance values mainly between 0.17 and 0.41. These new data provide a minimum temperature of the flow of 240–320 °C, consistent with previous estimations determined from independent field, engineering, and medical observations published in the literature for this eruption. A few charcoal fragments recorded higher values, suggestive of temperatures up to 450 °C, and we suggest that this is due to the thermal disequilibrium of the deposits, with larger block-size clasts being much hotter than the surrounding ash matrix. Charring temperatures show no major differences between proximal and distal PDC deposits and are significantly lower than those that may be associated with a fast growing dome dominated by dense and vitric non-vesicular rocks. We therefore infer that the decrease in temperature from that at fragmentation (>900 °C) occurred in the very initial part of the current

Published

2018

6. Assessment of thermal evolution of Paleozoic successions of the Holy Cross Mountains (Poland)

Author

Alexandra Guedes, Amalia Spina, Simonetta Cirilli, Bruno Valentim, Claudia Romano, Domenico Grigo, Luca Aldega, Chiara Caricchi, Sveva Corrado, Matteo Trolese, Andrea Schito, Schito, Andrea, Corrado, Sveva, Trolese, Matteo, Aldega, Luca, Caricchi, Chiara, Cirilli, S., Grigo, Domenico, Guedes, A., Romano, Claudia, Spina, A., and Valentim, B.

Subjects

010506 paleontology, clay mineralogy, Holy Cross mountains, paleozoic source rocks, palynomorph darkness index, Raman spectroscopy, thermal maturity, vitrinite and organoclast reflectance, oceanography, geophysics, geology, economic geology, stratigraphy, Paleozoic, Paleozoic source rocks, Thermal maturity, Vitrinite and organoclast reflectance, Clay mineralogy, Raman spectroscopy, Palynomorph darkness index, Holy Cross Mountains, Stratigraphy, Acritarch, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Paleontology, chemistry.chemical_compound, Kerogen, Thermal maturity, Vitrinite, Geophysic, 0105 earth and related environmental sciences, biology, Paleozoic source rock, Maceral, Geology, biology.organism_classification, Clay mineralogy, Palynomorph darkness index, Holy Cross Mountain, Source rock, chemistry, Facies, Economic Geology, Vitrinite and organoclast reflectance, Conodont

Abstract

Poland is considered the most prospective country for shale gas production in Europe. Hydrocarbon generation/expulsion scenarios, drawn in the latest intensive exploration phases, tend to overestimate maturation levels when compared with brand new data acquired after recent drillings. We tested an integrated workflow to correlate published and original thermal maturity datasets for the Paleozoic to Jurassic successions cropping out in the Holy Cross Mountains. These successions, when preserved in subsurface, host the major source rocks in the area. The application of the workflow allowed us to highlight the burial and thermal evolutionary scenarios of the two tectono-stratigraphic blocks of the Holy Cross Mountains (Łysogory and Kielce blocks) and to propose this approach as a tool for reducing levels of uncertainty in thermal maturity assessment of Paleozoic successions worldwide. In particular, published datasets including colour alteration indexes of Paleozoic microfossils (conodont, acritarchs) and vitrinite and graptolite reflectance data, show differences in levels of thermal maturity for the Łysogory (mid mature to overmature) and Kielce (immature to late mature) blocks. Original data, derived from optical analysis, pyrolysis, and Raman spectroscopy on kerogen, and X-Ray diffraction on fine-grained sediments, mostly confirm and integrate published data distribution. 1D thermal models, constrained by these data, show burial and exhumation events of different magnitude, during the Late Cretaceous, for the Łysogory (maximum burial depths of 9 km) and Kielce (burial depths of 6 km) blocks that have been related to the Holy Cross Fault polyphase activity. In the end, Palynomorph Darkness Index and Raman spectroscopy on kerogen, for Llandoverian and Cambrian rocks, turned out to be promising tools for assessing thermal maturity of Paleozoic organic facies devoid of vitrinite macerals.

Published

2017