Active Fault Research Volume 2020, Issue 52

Detailed mapping of surface ruptures associated with the 2016 Kumamoto earthquake and faulting history of the conjugated fault in Dozon, Mashiki Town, Kumamoto Prefecture

　 On the 16 April Kumamoto earthquake (Mj7.3), ～31km-long right-lateral surface ruptures appeared along the previously mapped Futagawa and Hinagu faults. The surface ruptures appeared in Dozon, Mashiki Town, recording 2.2m of right-lateral displacement which is the maximum strike-slip displacement of these surface ruptures. Small surface deformations such as flexure of cultivated land and deformation of the waterway and left-lateral conjugated fault also appeared in this area. In order to reveal distribution and amount of small surface deformations, we created a digital surface model (DSM) based on photographs taken by unmanned aerial vehicle (UAV) and RTK-GPS survey and conducted a field survey. As a result, small and conjugated surface ruptures were observed about 100m northwest of the main trace of the strike-slip fault, and amount of these deformations are each about 5―30cm of north-down displacement. The amount of vertical offset of just above the main trace is 25―30cm of south-down offset but the total vertical offset in Dozon is a north-down vertical offset rather than a south-down when summing the vertical offset of the secondary trace and the main trace. We also conducted a trenching survey across the conjugated fault to reveal surface faulting history. While the vertical offset caused by the 2016 earthquake was 20cm down on the south, older strata exposed on the trench walls were offset more than 40cm. Based on the deformational features of exposed strata, we identified at least four faulting events including the 2016 earthquake. The timing of the event before the 2016 earthquake is 500―10,600yrsBP. It indicates that the conjugated fault is also cumulative. It is likely that the conjugated fault and small surface ruptures have repeatedly ruptured simultaneously with the main trace, because the conjugated fault follows the small surface ruptures and is consistent with the timing of events in the main trace.

Middle Holocene palaeoseismic history of Kozu-Matsuda Fault Zone inferred from off-fault palaeoseismological evidences in Ashigara Plain, central Japan

　 Middle Holocene palaeoseismic history of Kozu-Matsuda Fault Zone, central Japan, was studied by an off-fault paleoseismological survey. The Kozu-Matsuda Fault Zone is located between the Ashigara Plain and the Oiso Hills, and is a reverse fault uplifting the Oiso Hills relatively with quite high slip rate (～3.5m/ky). We conducted analyses on sedimentary facies, diatom fossil assemblages and tephra layers and radiocarbon dating of three boring cores, GS-ASG-3, M3, B-11 cores, in southeastern part of the Ashigara Plain. In the study area, freshwater marsh or channel environment occurred until ca. 7.9-8.1ka. This suggests that regressive stage began before ca. 7.9-8.1ka because sea-level rising became slower than before. Comparison of sedimentary environmental changes of boring cores suggests two coseismic subsidence events. These events were characterized by drastic environmental changes from freshwater marsh to tidal flat in the regressive stage in common among boring cores. Timings of these events were suggested to be ca. 7.6ka and ca. 6.8-6.9ka respectively. In addition, both of these events are corresponding to the coseismic events reported previously around the Oiso Hills.

Earthquake faults determined by gamma-ray survey

　 In our country, magnitude is determined by the length of existing active faults. The fracture width that can be detected by the gamma-ray survey is effective to understand the fault length. The type classification based on the fracture width as the active fault evaluation was shown by measuring the fracture width in various earthquake faults. The size of the geological faults is not specified. However, the classifying the source faults according to the length and width of the fracture is a technique of the technological evaluation in anti-earthquake procedures and seismic design.