Gulf of Corinth IODP Exp 381 Sediment supply rate variations
Lead Research Organisation:
University of Leeds
Department Name: School of Earth and Environment
Abstract
Rift basins evolve through subsidence on the downthrown side of faults and uplift of the rift flanks, on the upthrown side of the main rift faults. As a result, slopes in the surrounding landscape evolve through time in response to growing rift-related topography, but in competition with erosion that also occurs through time. The higher the slope angles (the higher the relief), the higher are the associated rates of erosion for any given climatic setting. Rates of sediment supply to the basin therefore provide a record of rift structural evolution over the life of an active rift. Sediment supply also interacts with rates of tectonic subsidence within the rift, and with any fluctuations in sea (or lake) level through time, to determine whether the basin is underfilled with sediment or alternatively gets progressively filled and ultimately overfilled with sediment. The Corinth Rift is currently underfilled, with water depths in excess of 800m, but there may have been periods of preferential infilling and other periods of basin deepening, for given tectonic subsidence rates, depending on the shorter-term rates of sediment input to the basin. The prediction of associated sedimentary geometries within rift basins is an important aspect of hydrocarbon exploration and so a better understanding of these processes could reduce uncertainties in commercial exploration efforts.
Studying a young and active marine continental rift system (of which there are only few in the world) means that we can date the sediments accurately, using a variety of absolute and relative dating methods. Over the last several ice ages, we also already have an accurate record and understanding of sea level changes and of palaeoclimate changes in the eastern Mediterranean region. This means that the new cores from Expedition 381 will allow detailed quantification of variations in sedimentation rates over the last few hundreds of thousands of years. This will allow us to establish for the first time the magnitude of variations in sediment erosion rates and transport into the rift during this interval, and how these variations in sedimentation rates relate to short-term climate fluctuations, over time periods of only thousands to tens of thousands of years. This will aid our understanding of how future changes in climate may impact upon sediment transfer from the onshore landscape to the offshore in a wider range of sedimentary basins.
Studying a young and active marine continental rift system (of which there are only few in the world) means that we can date the sediments accurately, using a variety of absolute and relative dating methods. Over the last several ice ages, we also already have an accurate record and understanding of sea level changes and of palaeoclimate changes in the eastern Mediterranean region. This means that the new cores from Expedition 381 will allow detailed quantification of variations in sedimentation rates over the last few hundreds of thousands of years. This will allow us to establish for the first time the magnitude of variations in sediment erosion rates and transport into the rift during this interval, and how these variations in sedimentation rates relate to short-term climate fluctuations, over time periods of only thousands to tens of thousands of years. This will aid our understanding of how future changes in climate may impact upon sediment transfer from the onshore landscape to the offshore in a wider range of sedimentary basins.
Planned Impact
The work targets fundamental research on tectono-sedimentary interactions and rates of sedimentary process. However, this will provide important input to understanding and modelling of sequence stratigraphic geometries in modern and ancient rift basins worldwide. The interpretation of these geometries is critical in hydrocarbon exploration in syn-rift settings. An improved understanding of these tectonic/base level/sediment supply interactions may reduce interpretation uncertainty and lead to reduced risk estimations in drilling decisions.
The proposer regularly trains and presents to oil company geoscientists and a generic talk on the aims of Exp. 381 is already planned - for presentation to the Dhahran Geoscience Society in Saudi Arabia. Results will however not be released until the end of the moratorium period.
The Expedition 381 team has already run a number of outreach and public awareness events, most notably through Greek national news coverage of the onset of Exp. 381 drilling and through events facing the Athens Department of Geology and Geoenvironment. A blog is running and has been promoted for School students and others to follow. More education and outreach activities are planned for the onshore science party in Bremen. More generically, IODP has regular outreach activities associated with major international research conferences such as EGU, AGU and GSA.
The proposer regularly trains and presents to oil company geoscientists and a generic talk on the aims of Exp. 381 is already planned - for presentation to the Dhahran Geoscience Society in Saudi Arabia. Results will however not be released until the end of the moratorium period.
The Expedition 381 team has already run a number of outreach and public awareness events, most notably through Greek national news coverage of the onset of Exp. 381 drilling and through events facing the Athens Department of Geology and Geoenvironment. A blog is running and has been promoted for School students and others to follow. More education and outreach activities are planned for the onshore science party in Bremen. More generically, IODP has regular outreach activities associated with major international research conferences such as EGU, AGU and GSA.
People |
ORCID iD |
| Richard Collier (Principal Investigator) |
Publications
Kang W
(2022)
Grain-size analysis of the Late Pleistocene sediments in the Corinth Rift: insights into strait-influenced hydrodynamics and provenance of an active rift basin
in Geological Society, London, Special Publications
Mazzini I
(2023)
A new deglacial climate and sea-level record from 20 to 8 ka from IODP381 site M0080, Alkyonides Gulf, eastern Mediterranean
in Quaternary Science Reviews
McNeill LC
(2019)
Author Correction: High-resolution record reveals climate-driven environmental and sedimentary changes in an active rift.
in Scientific reports
McNeill LC
(2019)
High-resolution record reveals climate-driven environmental and sedimentary changes in an active rift.
in Scientific reports
Shillington D
(2019)
Expedition 381 Preliminary Report: Corinth Active Rift Development
| Description | Sedimentary architectures within rift basins are a product of accommodation variation through time, a record of the interplay between tectonic subsidence rates, sea or lake level through time, and sediment supply. A series of interlinked objectives fell under theme 2 "Surface processes in active rifts" of the original drilling proposal which led to Expedition 381, Corinth Active Rift Development. The theme aims to establish variations in rates of sediment supply through the evolution of the rift, on a variety of timescales. The aim was to establish long term trends (105-106 yr) in sediment flux in response to the tectono-geomorphological evolution of relief and drainage catchments around the rift, results now published in McNeill et al (2019). Secondly, the aim was to establish the magnitude of variance from these rates as a response to short-term (103-104 yr) palaeoclimatic variations and variations in palaeoenvironmental setting. Samples in this project have confirmed the presence of a significant number of volcanic ashes (tephra and cryptotephra) in International Ocean Discovery Programme borehole M0079A, from the Corinth Rift, Greece, with quartz shard separates generated for each ash sample. These were recovered from samples taken between seabed and depths of up to 315 metres below sea floor. Work is nearing completion on the chemical characterization by electron microprobe analysis of these volcanic ash deposits. Individual ash deposits have individual chemical signatures which may be tied back to proximal volcanic ash deposits in southern Italy where the source volcanoes are located. Proximal ash deposits have been dated radiometrically (results available through publically accessible databases) such that downhole ashes may be correlated with proximal ashes to determine their ages. When complete this will significantly improve the time resolution of the cored sedimentary sequence (back to about 200 ka) and so a allow higher resolution record of sediment flux variation to be characterized than that already presented in McNeill et al (2019). Electron microscopy laboratory time is already booked for this last stage of analysis. A parallel study has been carried out of the texture and compositions of samples of the carbonate muds recovered in borehole M0079A within the above stratigraphic interval. Microfacies differentiation not previously achieved in these carbonate muds has now been achieved through back-scatter electron microscopy and the novel application of Aztec software, which uses energy-dispersive x-ray spectroscopy (EDS) analyses to produce detailed chemical and morphological data (particle size, orientation, shape, chemistry). Together with back-scatter imagery, these results tell us about a) sediment transport processes, b) early diagenesis within the sedimentary column, and c) will allow future work to characterize the composition and erosional origin of fine-particle heavy mineral separates which will provide new information on provenance variation on a range of timescales (when results are integrated with the new high resolution age model for the borehole). The wider applicability of these analytical methods will be shared with the sedimentology community through conference presentation and publication (funded outside this particular grant). |
| Exploitation Route | The petroleum industry has a strong interest in understanding the sedimentary processes and sedimentary architectures of active rift basins, to gain improved understanding of ancient rift systems which are prospective for oil and gas exploration. Understanding the controls on sediment flux variation through time are a key component to this. Past seismic interpretation (sequence stratigraphic) methodologies have been built upon assumptions of constant sediment flux through time (or at best best sediment flux varying inversely with rises and falls in sea level through time. The results of this project are demonstrating much high frequency fluctuations in sediment flux than previously recognized. This will have impact upon predictions of subsurface architectures such as reservoir stacking patterns and connectivity. |
| Sectors | Education,Energy |
| Description | In addition to the petroleum industry having a strong interest in understanding the sedimentary processes and sedimentary architectures of active rift basins, to gain improved understanding of ancient rift systems which are prospective for oil and gas exploration, understanding the controls on sediment flux variation through time are a vital component of academic understanding of sedimentary basin evolution. Seismic interpretation (sequence stratigraphic) methodologies will be modified to take account of high frequency fluctuations in sediment flux than were previously recognized, and this is already being integrated into graduate level teaching of seismic interpretation. The project has also informed and provided support for a Norwegian Resaearch Council (Petromaks II) DeepRift reserach proposal on which I am a Co-I (Prof R Gawthorpe, PI, Univ. Bergen.). |
| First Year Of Impact | 2018 |
| Sector | Education,Energy |
| Description | Rift and rifted margin deep-water depositional systems: Application to Late Jurassic - Early Cretaceous rifting on the NCS |
| Amount | krĀ 32,360,000 (NOK) |
| Funding ID | 338805 |
| Organisation | University of Bergen |
| Sector | Academic/University |
| Country | Norway |
| Start | 10/2020 |
| End | 09/2023 |
| Title | National Geoscience Data Centre: Gulf of Corinth IODP Exp 381 Sediment Supply rate variations - tephra chronology for age model (133625) |
| Description | Dataset of Electron Probe Microanalyzer (EPMA) results of tephra compositions - visible tephra samples from IODP Exp 381 holes M0078A, M0079A and M0080A. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2020 |
| Provided To Others? | Yes |
| Impact | Work in progress. |
| URL | http://bgs.ac.uk |
| Description | Norwegian Centre of Excellence for Earth Science Teaching: iCorinth - Corinth Rift virtual field trip and teaching resource |
| Organisation | University of Bergen |
| Department | Department of Earth Science |
| Country | Norway |
| Sector | Academic/University |
| PI Contribution | Interest in the Plio-Pleistocene evolution of the Corinth Rift, Greece, has in recent years included the IODP Expedition 381 'Active Corinth Rift Development' offshore and involvement in major NFR funding for onshore field-based studies of palaeoclimatic change and rift evolution (e.g. Syn-Rift Systems project, 255229). As a result of these major research projects and current NFR-funded research in the Corinth Rift (DeepRift project, 308805), much of the underlying material and expertise is now available to develop an exciting virtual field trip teaching resource for the Corinth Rift - iCorinth. The overall vision behind the iCorinth initiative is to integrate field-based studies, including onshore fieldwork, with datasets collected during major marine geology and geophysical cruises to provide a teaching resource that spans traditional subjects. To achieve this overall aim the iCorinth project is subdivided into two phases. Phase 1 will develop a virtual field trip to the onshore Corinth Rift based on the active faults and geomorphology along the southern shores of the Gulf of Corinth and exceptional exposures of now abandoned Plio-Pleistocene structure and basin fill exposed in the northern Peloponnese. Phase 2 of iCorinth will develop a virtual marine cruise using seismic and bathymetry data from the Gulf of Corinth together with IODP Expedition 381 borehole data. As part of an international partnership, Collier will bring fieldwork expertise on the Corinth Rift to the project, together with shared geophysical data sets and digital outcrop data sets from parallel PhD projects supervised by Collier. |
| Collaborator Contribution | Gawthorpe will lead the project and be responsible for the overall development of the themes and component exercises in collaboration with Mary Ford (University of Lorraine), and Richard Collier (University of Leeds) who have extensive experience of the Corinth Rift. Early career researchers, Muravchik, Cullen, Nixon and Pechlivanidou at UiB have research experience of the Corinth rift and will be responsible for producing exercise material, including generation of digital outcrop models. Recently started masters students will also work on the Corinth Rift in developing exercises related to their masters theses. In order to integrate and standardise existing data and build the iCorinth virtual field trip a dedicated research assistant will be designated to the project for six months. |
| Impact | Not yet. |
| Start Year | 2020 |
| Description | PETROMAKS II project: Rift and rifted margin deep-water depositional systems: Application to Late Jurassic - Early Cretaceous rifting on the NCS (DeepRift) |
| Organisation | University of Bergen |
| Department | Department of Earth Science |
| Country | Norway |
| Sector | Academic/University |
| PI Contribution | Member of international partnership (Universities of Bergen, Leeds, Southampton, North Arizona, Imperial, Lorraine, Athens, Hellenic Centre for Marine Research) studying deepwater sediment flux and sedimentary process and architectures within active rift settings. The Gulf of Corinth is a principal research locale within this NRC and industry consortium-funded project. I will participate in a marine geophysics cruise in autumn 2021 and supervise a funded PhD student (Mohammed), charafcterising controls upon the architecure of base-of-slope submarine fans. I will also carry out fieldwork, including with my PhD students Arif and Alghamdi plus students from Bergen, as part of this project. |
| Collaborator Contribution | Work Package 1: Gulf of Corinth deep-water rift, from source to sink Work Package 2: Numerical modelling of rift evolution and surface processes Work package 3: Norwegian continetal shelf syn-rift deep-water systems Work package 4: Synthesis and application Overall project management will be led by Rob Gawthorpe (VISTA Professor, University of Bergen (UiB)). He will also lead Work Package 1 (WP1) and has worked on integrated structural and sedimentological studies of rift basins worldwide, and has extensive experience managing large, interdisciplinary, industry-focused projects, and researcher supervision. Huismans and Rotevatn (UiB) will lead WP2 and WP3, respectively. Pedersen provides AUV and geochemistry expertise, with Meckler supporting isotopic work (WP1), Cowie surface processes in rifts (WP2), and Lecomte seismic modelling (WP3) (all UiB). Jackson (Imperial, sabbatical in UiB 20/21) brings extensive NCS rift structure knowledge to WP2. Sakellariou (Hellenic Centre for Marine Research (HCMR)), Shillington (Lamont-Doherty), McNeill (Southampton) provide marine geophysical survey design, acquisition, processing and interpretation expertise and have significant experience of the Corinth Rift (WP1), and include the IODP 381 leaders. Collier (Leeds), Ford (Lorraine) and Kranis, Kouli, Skourtsos (Athens) bring Corinth expertise. |
| Impact | Abstract: Fabregas, N., Pechlivinadou, S., Gawthorpe, R., Ford, M. & Collier R. Deep-water syn-rift sedimentary response to alternating Late Quaternary palaeoenvironments in the Gulf of Corinth (Greece). EGU21-2414, EGU General AAssembly 2021. |
| Start Year | 2020 |