New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data
The Mt. Melbourne field is interpreted as a quiescent volcanic complex, located in Northern Victoria Land, Antarctica, at the boundary between the Transantarctic Mountains (TAM) and the West Antarctic Rift System (WARS). It is one of the handful Antarctic volcanoes with the potential for large–scale...
| Main Authors: | , , , , |
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| Other Authors: | , , , , |
| Format: | Conference Object |
| Language: | English |
| Published: |
2020
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| Subjects: | |
| Online Access: | http://hdl.handle.net/11567/1024106 |
| _version_ | 1821702753512062976 |
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| author | Alessandro Ghirotto Egidio Armadillo Laura Crispini Andrea Zunino Fausto Ferraccioli |
| author2 | Ghirotto, Alessandro Armadillo, Egidio Crispini, Laura Zunino, Andrea Ferraccioli, Fausto |
| author_facet | Alessandro Ghirotto Egidio Armadillo Laura Crispini Andrea Zunino Fausto Ferraccioli |
| author_sort | Alessandro Ghirotto |
| collection | Università degli Studi di Genova: CINECA IRIS |
| description | The Mt. Melbourne field is interpreted as a quiescent volcanic complex, located in Northern Victoria Land, Antarctica, at the boundary between the Transantarctic Mountains (TAM) and the West Antarctic Rift System (WARS). It is one of the handful Antarctic volcanoes with the potential for large–scale explosive eruptions [1], with resulting key effects on the local environment and potentially on climate. The geological and geophysical structure of this volcanic field remains poorly known, despite its key relevance to better comprehend the Cenozoic tectonic and geodynamic processes responsible for the opening of the WARS and the uplift of the TAM rift flank. Here we present results derived from a novel high–resolution aeromagnetic dataset, collected in the austral summer 2002/2003 during the XVIII Italian Expedition, with the aim of investigating the geophysical structure of the main volcanic centres of the field. Aeromagnetic data were processed and Digital Enhancement and Depth to Magnetic Source analysis performed to reveal the distribution of the main fault systems affecting the Mt. Melbourne volcanic field, particularly beneath the ice–covered areas. The results highlight NNE–SSW, NW–SE and E–W trending structural systems, in agreement with the available tectonic information for the study area [2, 3]. Furthermore, similar NNW–SSE trending pervasive negative anomalies are detected beneath both the Mt. Melbourne edifice and Cape Washington, superimposed by positive ones forming radial patterns. With the aid of laboratory magnetic susceptibility data from rock samples collected in the field [4], we carried out forward and inverse modeling across the volcanic centres in order to image their subglacial internal structure. Based on our results, considering the ambiguity and narrowness of the available geochronological data [1, 5, 6], we propose two (non–mutually exclusive) interpretative models to explain the evolution steps of the Mt. Melbourne volcanic complex. In the former, a major volcanic phase responsible for ... |
| format | Conference Object |
| genre | Antarc* Antarctic Antarctica Victoria Land ice covered areas |
| genre_facet | Antarc* Antarctic Antarctica Victoria Land ice covered areas |
| geographic | Antarctic Austral Cape Washington Transantarctic Mountains Victoria Land |
| geographic_facet | Antarctic Austral Cape Washington Transantarctic Mountains Victoria Land |
| id | ftunivgenova:oai:iris.unige.it:11567/1024106 |
| institution | Open Polar |
| language | English |
| long_lat | ENVELOPE(-154.800,-154.800,-78.100,-78.100) |
| op_collection_id | ftunivgenova |
| op_relation | ispartofbook:EGU General Assembly 2020 Abstracts EGU General Assembly 2020 firstpage:1 lastpage:1 numberofpages:1 http://hdl.handle.net/11567/1024106 |
| publishDate | 2020 |
| record_format | openpolar |
| spelling | ftunivgenova:oai:iris.unige.it:11567/1024106 2025-01-16T19:16:03+00:00 New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data Alessandro Ghirotto Egidio Armadillo Laura Crispini Andrea Zunino Fausto Ferraccioli Ghirotto, Alessandro Armadillo, Egidio Crispini, Laura Zunino, Andrea Ferraccioli, Fausto 2020 ELETTRONICO http://hdl.handle.net/11567/1024106 eng eng ispartofbook:EGU General Assembly 2020 Abstracts EGU General Assembly 2020 firstpage:1 lastpage:1 numberofpages:1 http://hdl.handle.net/11567/1024106 info:eu-repo/semantics/conferenceObject 2020 ftunivgenova 2024-01-03T18:01:27Z The Mt. Melbourne field is interpreted as a quiescent volcanic complex, located in Northern Victoria Land, Antarctica, at the boundary between the Transantarctic Mountains (TAM) and the West Antarctic Rift System (WARS). It is one of the handful Antarctic volcanoes with the potential for large–scale explosive eruptions [1], with resulting key effects on the local environment and potentially on climate. The geological and geophysical structure of this volcanic field remains poorly known, despite its key relevance to better comprehend the Cenozoic tectonic and geodynamic processes responsible for the opening of the WARS and the uplift of the TAM rift flank. Here we present results derived from a novel high–resolution aeromagnetic dataset, collected in the austral summer 2002/2003 during the XVIII Italian Expedition, with the aim of investigating the geophysical structure of the main volcanic centres of the field. Aeromagnetic data were processed and Digital Enhancement and Depth to Magnetic Source analysis performed to reveal the distribution of the main fault systems affecting the Mt. Melbourne volcanic field, particularly beneath the ice–covered areas. The results highlight NNE–SSW, NW–SE and E–W trending structural systems, in agreement with the available tectonic information for the study area [2, 3]. Furthermore, similar NNW–SSE trending pervasive negative anomalies are detected beneath both the Mt. Melbourne edifice and Cape Washington, superimposed by positive ones forming radial patterns. With the aid of laboratory magnetic susceptibility data from rock samples collected in the field [4], we carried out forward and inverse modeling across the volcanic centres in order to image their subglacial internal structure. Based on our results, considering the ambiguity and narrowness of the available geochronological data [1, 5, 6], we propose two (non–mutually exclusive) interpretative models to explain the evolution steps of the Mt. Melbourne volcanic complex. In the former, a major volcanic phase responsible for ... Conference Object Antarc* Antarctic Antarctica Victoria Land ice covered areas Università degli Studi di Genova: CINECA IRIS Antarctic Austral Cape Washington ENVELOPE(-154.800,-154.800,-78.100,-78.100) Transantarctic Mountains Victoria Land |
| spellingShingle | Alessandro Ghirotto Egidio Armadillo Laura Crispini Andrea Zunino Fausto Ferraccioli New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data |
| title | New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data |
| title_full | New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data |
| title_fullStr | New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data |
| title_full_unstemmed | New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data |
| title_short | New insights into the evolution of the Mt. Melbourne volcanic field (Northern Victoria Land, Antarctica) from high–resolution aeromagnetic data |
| title_sort | new insights into the evolution of the mt. melbourne volcanic field (northern victoria land, antarctica) from high–resolution aeromagnetic data |
| url | http://hdl.handle.net/11567/1024106 |