Stress Field Interactions Between Overlapping Shield Volcanoes: Borehole Breakout Evidence From the Island of Hawai'i, USA

Knowledge of the in situ stress state of the Earth's crust plays a key role in understanding geological processes including plate tectonics, earthquakes, slope failure, and igneous emplacement. In this paper, we determine the in situ stress orientation from the PTA2 borehole on the island of Ha...

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Veröffentlicht in:	Journal of geophysical research. Solid earth 2020-08, Vol.125 (8), p.n/a
Hauptverfasser:	Pierdominici, Simona, Millett, John M., Kück, Jochem K. M., Thomas, Donald, Jerram, Dougal A., Planke, Sverre, Haskins, Eric, Lautze, Nicole, Galland, Olivier
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Sprache:	eng
Schlagworte:	Accumulation Acoustic images Ascent borehole breakout Boreholes Compressive properties Earth crust Earthquakes Geological processes Geophysics Gravitational collapse Gravitational fields Gravity Hawaii Lava Lava flows Magma Mauna Kea Orientation Plate tectonics Plates (tectonics) present‐day stress field Seismic activity Stress Stress distribution Stress state Tectonics USA Volcanic activity Volcanic islands Volcanic rocks volcano Volcanoes
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creator	Pierdominici, Simona Millett, John M. Kück, Jochem K. M. Thomas, Donald Jerram, Dougal A. Planke, Sverre Haskins, Eric Lautze, Nicole Galland, Olivier
description	Knowledge of the in situ stress state of the Earth's crust plays a key role in understanding geological processes including plate tectonics, earthquakes, slope failure, and igneous emplacement. In this paper, we determine the in situ stress orientation from the PTA2 borehole on the island of Hawai'i, drilled into a lava flow dominated sequence between Mauna Kea and Mauna Loa. High‐resolution acoustic images were collected from the open hole interval 886 m to 1,567 m. Based on identification of 371 borehole breakouts for a total length of 310 m, the mean orientation of the minimum horizontal principal stress is N106° and remains constant across different volcanic rock fabrics. Changes in borehole breakout shape are linked to the different strength of volcanic facies and intra‐facies. The orientation of the present‐day stress field at Mauna Kea deviates from the plate forces and regional tectonic stress field. We interpret the compressive stress regime at the PTA2 site as resulting from the competing gravitational fields of the large topographic highs of Mauna Kea and Mauna Loa. Our study reveals that the mass accumulation associated with shield volcano growth imparts significant local variations to the subsurface stress state on volcanic islands consisting of overlapping shield volcanoes. The results have significant implications for stress accumulation leading to brittle failure and flank collapse, along with potentially influencing magma accumulation and ascent pathways during volcanic island evolution. This study provides the first insights into the orientation of the present‐day stress field between the major island forming shield volcanoes of Hawai'i. Key Points First documentation of the subsurface in situ stress state between the major island forming shield volcanoes of Mauna Loa and Mauna Kea Borehole breakouts analysis constrains the present‐day stress field between large shield volcanoes on the island of Hawai'i Stress state evolution is linked to the progressive build up and interaction of gravitational loads between large shield volcanoes
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Based on identification of 371 borehole breakouts for a total length of 310 m, the mean orientation of the minimum horizontal principal stress is N106° and remains constant across different volcanic rock fabrics. Changes in borehole breakout shape are linked to the different strength of volcanic facies and intra‐facies. The orientation of the present‐day stress field at Mauna Kea deviates from the plate forces and regional tectonic stress field. We interpret the compressive stress regime at the PTA2 site as resulting from the competing gravitational fields of the large topographic highs of Mauna Kea and Mauna Loa. Our study reveals that the mass accumulation associated with shield volcano growth imparts significant local variations to the subsurface stress state on volcanic islands consisting of overlapping shield volcanoes. 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subjects	Accumulation Acoustic images Ascent borehole breakout Boreholes Compressive properties Earth crust Earthquakes Geological processes Geophysics Gravitational collapse Gravitational fields Gravity Hawaii Lava Lava flows Magma Mauna Kea Orientation Plate tectonics Plates (tectonics) present‐day stress field Seismic activity Stress Stress distribution Stress state Tectonics USA Volcanic activity Volcanic islands Volcanic rocks volcano Volcanoes
title	Stress Field Interactions Between Overlapping Shield Volcanoes: Borehole Breakout Evidence From the Island of Hawai'i, USA
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