Your search keyword '"Keitaro KOMURA"' showing total 3 results

1. Shortcut Faults and Lateral Spreading Activated in a Pull-Apart Basin by the 2018 Palu Earthquake, Central Sulawesi, Indonesia

Author

Jun Sugimoto and Keitaro Komura

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, optical correlation, Science, Alluvial fan, Pull apart basin, Active fault, Structural basin, Fault (geology), 2018 Palu earthquake, basin-shortcut fault, 010502 geochemistry & geophysics, 01 natural sciences, atmospheric_science, pull-apart basin, General Earth and Planetary Sciences, lateral spreading, Optical correlation, Digital elevation model, Seismology, Geology, 0105 earth and related environmental sciences

Abstract

Our understanding of pull-apart basins and their fault systems has been enhanced by analog experiments and simulations. However, there has been no opportunity to compare the faults that constitute pull-apart basins with surface ruptures during earthquakes. In this study, we investigated the effects of a 2018 earthquake (Mw 7.5) on a pull-apart basin in the Palu-Koro fault system, Sulawesi Island, Indonesia, using geomorphic observations in digital elevation models, optical correlation with pre- and post-earthquake satellite images. A comparison of active fault traces determined by geomorphology with the locations of surface ruptures from the 2018 earthquake shows that some of the boundary faults of the basin are inactive and that active faulting has shifted to basin-shortcut faults and relay ramps. We also report evidence of lateral spreading, in which alluvial fan materials moved around the end of the alluvial fan. These phenomena may provide insights for anticipating the location of future surface ruptures in pull-apart basins.

Published

2021

2. Surface rupture and characteristics of a fault associated with the 2011 and 2016 earthquakes in the southern Abukuma Mountains, northeastern Japan, triggered by the Tohoku-Oki earthquake

Author

Kotaro Aiyama, Takahiro Nagata, Yasuhira Aoyagi, Keitaro Komura, Hiroshi Sato, and Akihiro Yamada

Subjects

lcsh:Geodesy, Paleoseismology, Active fault, Fault (geology), Megathrust earthquake, InSAR, Lidar DEM, Surface rupture, Fault fracture zone, Interferometric synthetic aperture radar, Normal fault, lcsh:QB275-343, geography, geography.geographical_feature_category, Subduction, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, Trench excavation, Geology, lcsh:Geology, Tectonics, lcsh:G, Space and Planetary Science, Trench, Seismology

Abstract

The 2011 Tohoku-Oki offshore subduction earthquake (Mw 9.0) triggered many normal-type earthquakes inland in northeastern Japan. Among these were two very similar normal-faulting earthquakes in 2011 (Mw 5.8) and 2016 (Mw 5.9), which created surface ruptures along the newly named Mochiyama fault within the southern Abukuma Mountains, northeastern Japan, where no active faults had been previously mapped by interpretation of aerial photographs. We conducted field surveys in this area immediately after both earthquakes, and we performed trench excavations and observations of fault fracture zones after the 2016 event. These activities were complemented by an interferometric synthetic aperture radar analysis that mapped the areas of deformation and locations of surface discontinuities for both events. The combined results document the coseismic behavior of the Mochiyama fault during both events. Subtle tectonic geomorphic features associated with the fault were evident in a lidar digital elevation model of the area, and layered structures of gouge were documented in the field. These lines of evidence indicate repeated activity at shallow crustal levels and the possibility of Quaternary activity. In addition, our trench excavations revealed at least one faulting event before 2011. Our comparison of paleoseismic records on this and two other normal faults in the Abukuma Mountains suggests that great earthquakes in the Japan Trench supercycle of 500–700 years do not consistently trigger ruptures on these faults, and the case of 2011, in which the Tohoku-Oki megathrust earthquake triggered all three faults, is a rare occurrence.

Published

2019

3. Synchronized gravitational slope deformation and active faulting: A case study on and around the Neodani fault, central Japan

Author

Satoru Kojima, Heitaro Kaneda, Tomohiro Nishio, Tomoki Tanaka, Tsutomu Inoue, and Keitaro Komura

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Deformation (mechanics), Paleoseismology, Excavation, Active fault, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Trench, Geology, Seismology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Earthquakes are considered to be important triggers of deep-seated gravitational slope deformation (DGSD) in seismically active regions, and if that is the case, DGSD features could be candidates for off-fault paleoseismology investigations. On the basis of pit excavations and sediment cores at an off-fault DGSD site and a trench excavation across the active Neodani fault at a nearby site, we examined the records of DGSD and surface-rupturing paleoearthquakes of the Neodani fault. The four most recent DGSD events were dated at after 240 cal BP, 1710–340 cal BP, 4730–3970 cal BP, and 5570–5340 cal BP. The four most recent surface-rupturing earthquakes were dated at 1891 CE (the Nobi earthquake), 2010–1220 cal BP, 7180–2110 cal BP, and before 9540 cal BP. We conclude that the ages of the four DGSD events are consistent with surface-rupturing earthquakes on the adjacent Neodani fault. We infer that static crustal strain from repeated seismogenic faulting plays an important role in the occurrence of DGSD events, at least in the immediate vicinity of active faults, although coseismic severe shaking would have at least some effect on them. Our case study suggests that off-fault DGSDs can be used to reconstruct or refine the paleoseismic history of a nearby active fault. We propose that an ideal DGSD for that purpose would be located in an area of concentrated strain near a termination, bend, or stepover of the target fault.

Published

2020