TY - JOUR
T1 - Emplacement history of volcaniclastic turbidites around the central Azores volcanic islands
T2 - Frequencies of slope landslides and eruptions
AU - Chang, Yu Chun
AU - Mitchell, Neil C.
AU - Schindlbeck-Belo, Julie C.
AU - Hansteen, Thor H.
AU - Freundt, Armin
AU - Hübscher, Christian
AU - Quartau, Rui
N1 - Funding Information:
The government of Taiwan funded this Ph.D. research with a scholarship. Radiocarbon dating was funded by the Natural Environmental Research Council (NERC) support for Natural Environment Isotope Facility (NEIF grant 2330.0920). The British Geophysical Association Gray-Milne funded attendance at the European Geoscience Union General Assembly 2022, where some of these ideas were discussed. Travel to Germany was funded by an International Exchanges grant from the Royal Society (IES\R3\170081). Further support was provided by NERC grant NE/T014814/1.
Funding Information:
We thank the scientific party and crew of RV Meteor during cruise M141/1 for their work in collecting the gravity cores. This cruise was funded by the DFG (German Research Foundation) and GEOMAR. We also acknowledge the project “Features of Azores and Italian Volcanic Islands (FAIVI),” supported by the European Communities 7th Framework Programme under EUROFLEETS grant agreement no. 228344, which allowed the acquisition of multibeam bathymetry around Terceira Island. John Moore, Jon Yarwood, and Tom Bishop of Manchester Geography Laboratories were very helpful in providing laboratory space and access to a high-power optical microscope for sample preparation. Bor-Jiun Jong, Shunwen Yu, Pei-Chen Kuo, and Chia-Hsin Tsai are thanked for sharing their experience on sample preparation for radiocarbon analysis. Thanks also to Chih-Kai Chuang for sharing his knowledge and experience of identifying foraminiferal species and to Dr. Philippa Ascough for assisting in the Natural Environmental Research Council (NERC) radiocarbon grant application and project management. We especially thank the staff in the environmental Radiocarbon Laboratory at Scottish Universities of Environmental Research Centre for carrying out the radiocarbon analyses. We thank also Science Editor Andrea Hampel and reviewers Adriano Pimentel and Fabiano Gam-beri for providing thoughtful comments on the submitted article, which significantly improved it.
Publisher Copyright:
© 2023 The Authors
PY - 2023
Y1 - 2023
N2 - Volcanic islands export clastic material to their surrounding oceans by explosive eruptions, lava emissions, biogenic production on their shelves, and failure of their slopes, amongst other processes. This raises the question of whether geological events (in particular, eruptions and landslides) can be detected offshore and dated, and whether any relationships (for example, with climate changes) can be revealed using sediment cores. The volca-nically active central Azorean islands (Faial, Pico, São Jorge, and Terceira), with their neighboring submarine basins, are potentially good candidates for such an analysis. Here, chronostratigraphies of four gravity cores collected amongst the islands are constructed based on twelve radiocarbon dates and two dates derived by geochemically correlating primary volcaniclastic turbidites with ignimbrites on Faial and Terceira Islands. Age-depth models are built from the hemipelagic intervals to estimate individual turbidite dates. Volumes of turbidites are modeled by multiplying basin areas with bed thick-ness, allowing for various turbidite thinning rates and directions. The volumes of landslide-generated turbidites are only comparable with the largest volumes of their adjacent upper-slope submarine landslide valleys; therefore, such turbidites in the cores likely derive from these largest landslides. Emplacement intervals between turbidites originating from both landslides and pyroclastic density currents are found to be mostly a few thou-sand years. Frequencies of landslide-generated turbidites and hemipelagic sedimentation rates were both highest in the past 8 k.y. compared to preceding periods up to 50 k.y. High hemipelagic sedimentation rates are interpreted to be related to sea-level rise, allowing more shelf bioproduc-tion and release of particles by coastal erosion. The coincident increased frequencies of subma-rine landslides may also be associated with the increased sediment supply from the islands, result-ing in a more rapid build-up of unstable sediments on submarine slopes. Notably, the emplacement frequencies of turbidites of pyroclastic density current origins do not suggest the decreased erup-tion frequency toward the Holocene that has been found elsewhere.
AB - Volcanic islands export clastic material to their surrounding oceans by explosive eruptions, lava emissions, biogenic production on their shelves, and failure of their slopes, amongst other processes. This raises the question of whether geological events (in particular, eruptions and landslides) can be detected offshore and dated, and whether any relationships (for example, with climate changes) can be revealed using sediment cores. The volca-nically active central Azorean islands (Faial, Pico, São Jorge, and Terceira), with their neighboring submarine basins, are potentially good candidates for such an analysis. Here, chronostratigraphies of four gravity cores collected amongst the islands are constructed based on twelve radiocarbon dates and two dates derived by geochemically correlating primary volcaniclastic turbidites with ignimbrites on Faial and Terceira Islands. Age-depth models are built from the hemipelagic intervals to estimate individual turbidite dates. Volumes of turbidites are modeled by multiplying basin areas with bed thick-ness, allowing for various turbidite thinning rates and directions. The volumes of landslide-generated turbidites are only comparable with the largest volumes of their adjacent upper-slope submarine landslide valleys; therefore, such turbidites in the cores likely derive from these largest landslides. Emplacement intervals between turbidites originating from both landslides and pyroclastic density currents are found to be mostly a few thou-sand years. Frequencies of landslide-generated turbidites and hemipelagic sedimentation rates were both highest in the past 8 k.y. compared to preceding periods up to 50 k.y. High hemipelagic sedimentation rates are interpreted to be related to sea-level rise, allowing more shelf bioproduc-tion and release of particles by coastal erosion. The coincident increased frequencies of subma-rine landslides may also be associated with the increased sediment supply from the islands, result-ing in a more rapid build-up of unstable sediments on submarine slopes. Notably, the emplacement frequencies of turbidites of pyroclastic density current origins do not suggest the decreased erup-tion frequency toward the Holocene that has been found elsewhere.
UR - http://www.scopus.com/inward/record.url?scp=85163044835&partnerID=8YFLogxK
U2 - 10.1130/GES02570.1
DO - 10.1130/GES02570.1
M3 - Article
AN - SCOPUS:85163044835
SN - 1553-040X
VL - 19
SP - 654
EP - 675
JO - Geosphere
JF - Geosphere
IS - 3
ER -