or
Looking to list your PhD opportunities? Log in here.
*Please note that this PhD will be hosted at Swansea University*
The coastal Neapolitan area (Italy) is one of the most densely populated volcanic regions in the world; more than three million people live within 10 km of the active volcanoes of Campi Flegrei, Vesuvius and Ischia, and are at risk from explosive volcanism. Campi Flegrei is showing increasing signs of unrest focusing attention on the associated risks to the region[1]. Accurately reconstructing the eruptive histories of these volcanoes, including determining the frequency and magnitude of past explosive activity, is a critical to forecasting future eruption scenarios and hazard assessments, both for the Neapolitan area, but also the wider Central Mediterranean at risk from widespread ash fall events.
However there remains a significant problem, volcanic reconstructions largely focus on near-source eruption records, which are inherently fragmentary, resulting in eruption under-recording[2-4]. Gaps in the eruption record are more acute further back in time and, as such, reconstructions are biased towards more recent and better-preserved records, which only provide short snapshots in time and do not reflect the full range and frequency of volcanic activity. Low- to mid-intensity explosive eruptions are particularly susceptible to under-recording, but the problem also extends to large magnitude events[5].
To overcome this problem, this project will capitalise on the huge potential of long, undisturbed records of ash (tephra) fall events preserved in sedimentary archives (e.g. lacustrine/marine cores) far from the volcano, to fill the gaps in eruption records. The student will exploit microscopic ash layers (known as cryptotephra) as a tool for resolving the low- to mid-intensity explosive eruptions. The initial focus will be on identifying cryptotephra layers preserved in the iconic Lake Ohrid (DEEP site) sedimentary archive. This record from the Balkans, was cored as part of the International Continental Drilling Program (ICDP), and spans a continuous and unrivalled 1.364 million years of Mediterranean climate history[6]. Critically, this sediment record is ideally located down-wind of the active Neapolitan volcanoes, and is an ideal depositional site/basin for preserving an undisturbed record of ash fall events[7].
The project aims to; (1) reconstruct a long, comprehensive ash fall record from the Lake Ohrid sediments spanning approximately the last 150,000 years; (2) integrate these ash fall events with those recorded in other distal archives to better constrain the timing, scale and ash dispersal patterns of past Neapolitan explosive eruptions, including through the use of ash dispersion models; (3) use the cryptotephra layers traced across Mediterranean palaeoclimate archives as time-markers to assess the regional development of past climate changes spanning the last interglacial-glacial cycle.
The student will undertake a range of laboratory based volcanic investigations, for instance, density separation techniques will be employed to extract and identify cryptotephra, while major (EMP) and trace element (LA-CP-MS) glass geochemistry will be used to determine their volcanic source, and identify potential source eruptions. These geochemical fingerprints will also be used to correlate the Lake Ohrid cryptotephra layers to those ash fall deposits preserved in other key regional sedimentary records. Reliably correlating ash fall layers between sedimentary successions will be essential for precisely constraining the fall footprint and scale of individual eruptions, whilst also accurately assessing eruption frequencies. The student will also explore the potential of refining the Lake Ohrid age-depth model by integrating existing absolute ages (e.g., 40Ar/39Ar) of those eruptions preserved in the near-source, and transferring them to Lake Ohrid record, via cryptotephra occurrences. Improved chronological constraints placed upon the record will enhance the potential to explore the spatio-temporal palaeoclimatic change across the Mediterranean region.
Training opportunities:
The student will receive training in field and laboratory based volcanic studies. They will be trained in sediment core logging and sampling, the extraction and identification of cryptotephra from within sedimentary successions. Furthermore, they will be trained to undertake analytical techniques used to chemically fingerprint the ash fall deposits identified, such as electron microprobe (EMP) and LA-ICP-MS analysis. The student will have the opportunity for field based volcanological training with regards to recording and sampling near-source tephra deposits. They will receive training in the application of computational and geochronological methods, used for age-depth modelling and ash dispersion modelling.
Student profile:
This project would be suitable for students with a degree in Geology / Physical Geography, or a closely related environmental or physical science.
How to apply
Applications are made through our Online Portal, Good Grants: https://crocus-dla.grantplatform.com/
Subject to a competition to identify the strongest applicants, this studentship would be fully funded by the Crocus NERC Doctoral Landscape Award.
Based on your current searches we recommend the following search filters.
Check out our other PhDs in Swansea, United Kingdom
Start a New search with our database of over 4,000 PhDs
Based on your current search criteria we thought you might be interested in these.
Retrodeformation and Phenomic Data Capture from Fossils to Reconstruct Response to Past Mass Extinction and Global Climate Change
University of Reading
Integrating Trophic Plasticity into Ecological Networks to Improve Climate Change Impact Predictions
Queen Mary University of London
Draw down of volcanic CO2 as a mechanism of climate recovery following periods of enhanced volcanism in Earth’s geological past
University of Oxford