Session outline
| Solid Earth Sciences (S) | ||
|---|---|---|
| Session Sub-category | Complex & General(CG) | |
| Session ID | S-CG65 | |
| Title | Dynamics in mobile belts | |
| Short Title | Dynamics in mobile belts | |
| Main Convener | Name | Yukitoshi Fukahata |
| Affiliation | Disaster Prevention Research Institute, Kyoto University | |
| Co-Convener 1 | Name | Hikaru Iwamori |
| Affiliation | Earthquake Research Institute, The University of Tokyo | |
| Co-Convener 2 | Name | Kiyokazu Oohashi |
| Affiliation | National Institute of Advanced Industrial Science and Technology | |
| Session Language |
E |
|
| Scope |
The dynamic behaviors of mobile belts are expressed across a wide range of time scales, from the seismic and volcanic events that impact society during our lifetimes, to orogeny and the formation of large-scale fault systems which can take place over millions of years. Deformation occurs on length scales from microscopic fracture and flow to macroscopic deformation to plate-scale tectonics. To gain a physical understanding of the dynamics of mobile belts, we must determine the relationships between deformation and the driving stresses associated with plate motion and other causes, which are connected through the rheological properties of the materials. To understand the full physical system, an integration of geophysics, geomorphology, geology, petrology, and geochemistry is necessary, as is the integration of observational, theoretical and experimental approaches. In particular, rheological properties, which are physically affected by fluids in the crust and chemical reactions assisted by fluids, can be resolved only through such an interdisciplinary approach. Frequent large earthquakes, such as the 2011 Tohoku-oki, the 2016 Kumamoto, and the 2024 Noto Peninsula Earthquakes, which were accompanied by significant changes in seismic activity and crustal deformation, making present-day Japan a unique natural laboratory for the study of the dynamics of mobile belts. This session welcomes presentations from different disciplines, such as seismology, geodesy, tectonic geomorphology, structural geology, petrology, geochemistry and hydrology, as well as interdisciplinary studies, that relate to the dynamic behaviors of mobile belts. |
|
| Presentation Format | Oral and Poster presentation | |
| Time | Presentation No | Title | Presenter |
|---|---|---|---|
| Oral Presentation May 29 AM2 | |||
| 10:45 - 11:00 | SCG65-01 | Toward better constraints on the thermal structure of subduction zones: a case study of the Tohoku region, Northeast Japan | Manabu Morishige |
| 11:00 - 11:15 | SCG65-02 | Rheological modeling for assessing the effect of seamount subduction | Erika Moreno |
| 11:15 - 11:30 | SCG65-03 | Fold Structures and Depositional Evolution at the Margin of the Hidaka Trough: Insights from Reprocessed Seismic Data Analysis | Hiroto Yamaguchi |
| 11:30 - 11:45 | SCG65-04 |
Improved Seismic Travel Time Tomography in the Southern Taiwan Subudction-Collision Transition Using SALUTE and AI-Assisted Phase Picking |
Shu-Huei Hung |
| 11:45 - 12:00 | SCG65-05 | Geofluid mapping based on the simultaneous analysis of seismic velocity and electrical conductivity and its implications for crustal dynamics | Hikaru Iwamori |
| 12:00 - 12:15 | SCG65-06 | Quantifying the distribution of crustal geofluids beneath Southeast Tibet | Zhang Chunjie |
| Oral Presentation May 29 PM1 | |||
| 13:45 - 14:00 | SCG65-07 | Estimation of a strain-rate field in southeastern Tibet by joint inversion of GNSS and InSAR data using basis function expansion with ABIC | Yohei Nozue |
| 14:00 - 14:15 | SCG65-08 | Tectonic stress and rheology estimates for Eurasia and Japan through Bayesian inversion of GNSS velocities | Rob Govers |
| 14:15 - 14:30 | SCG65-09 | Volcanic Subsidence Triggered by the 2025 Kamchatka Earthquake Detected by InSAR: Local Crustal Deformation Induced by Rheological Heterogeneity | Mikoto Yasue |
| 14:30 - 14:45 | SCG65-10 | Localized Deformation in the Northern Part of the Hida Mountain Range Associated with the 2024 Noto Peninsula Earthquake: Dense Geodetic Observation and Physical Modeling | Shogo Nagaoka |
| 14:45 - 15:00 | SCG65-11 | Modeling Stress Concentration and Relaxation in the Crust of Kyushu, Japan, using Seismic and Geodetic Observations Data | Yushi Nagayama |
| 15:00 - 15:15 | SCG65-12 | An Energy-based Model for the Generation of the 2016 Kumamoto Earthquake, Japan | Angela Meneses-Gutierrez |
| Oral Presentation May 29 PM2 | |||
| 15:30 - 15:45 | SCG65-13 | Stress Orientation Around the Japan Trench Inferred from Focal Mechanism Solutions of Small Earthquakes | Takahiko Uchide |
| 15:45 - 16:00 | SCG65-14 | Understanding earthquake generation based on stress and strain changes using DEFS | Toshiko Terakawa |
| 16:00 - 16:15 | SCG65-15 | Quasi-dynamic earthquake sequence simulation on the East Anatolian Fault Zone (Türkiye) with a branched fault system | Muneshige Takahashi |
| 16:15 - 16:30 | SCG65-16 | Rupture Dynamics on a 3D Branching Fault: Why the 2007 Mw 6.6 Noto Peninsula Earthquake Did Not Propagate into the 2024 Mw 7.5 Source Area | Mayuko Emori |
| 16:30 - 16:45 | SCG65-17 | Why did the 1984 Western Nagano Prefecture earthquake (Mj6.8) occurred (ser.3) | Yoshihisa Iio |
| 16:45 - 17:00 | SCG65-18 | Theoretical basis of the back-projection method for imaging dynamic rupture processes from seismic waveform data | Mitsuhiro Matsuura |
| Presentation No | Title | Presenter |
|---|---|---|
| Poster Presentation May 29 PM3 | ||
| SCG65-P01 | Reassessing Dual-Layer Crustal Anisotropy Beneath the Southern Taiwan Orogen with SALUTE and Adjoint-State Travel-time Tomography | Davin Mathews David |
| SCG65-P02 | Evolving crustal anisotropy in the Northeastern Japan revealed from two decades of shear wave splitting measurements | Muhammad Haikal Gunarya |
| SCG65-P03 | Revisiting the van Keken et al. (2008) subduction zone benchmark with ASPECT | Hang Zhang |
| SCG65-P04 | Water behavior in quartz during the formation of the Nihonkoku mylonite, NE Japan | Kenta Kobayashi |
| SCG65-P05 | Fault architecture beneath the Northern Fossa Magna rift basin constrained by fault-related fold modeling | Naoki ITO |
| SCG65-P06 | Development of shear zones and fault systems along a volcanic front in a strike-slip stress regime | Bunichiro Shibazaki |
| SCG65-P07 | Re-evaluating the exhumation history of the Tanzawa plutonic complex using thermochronology and one-dimensional thermal modeling | Saki Minami |
| SCG65-P08 | Detection of Interseismic Crustal Deformation around the Median Tectonic Line in Central Japan by InSAR and GNSS: A Preliminary Report | Youichiro Takada |
| SCG65-P09 | Shear strain energy change in eastern Japan before and after 2011 Tohoku-oki earthquake | Takeshi Shinjo |
| SCG65-P10 | Estimation of normalized deviatoric stress field through seismic moment stacking using first P-wave polarity data | Satoshi Matsumoto |
| SCG65-P11 | Stress heterogeneity in the seismogenic layer in the southern Yatsushiro Sea, Kyushu, Japan. | serika mishima |
| SCG65-P12 | Dynamic rupture simulation on the 2025 Mandaley, Myanmar Earthquake : 450km-long super-shear rupture | Motomasa Murata |
| SCG65-P13 | Estimation of the strain field around Mt. Fuji using changes in baseline length between GPS observation stations | Akinori Hashima |
| SCG65-P14 | Semi-analytical expressions of gravitational effects on viscoelastic deformations and their characteristics | Tadashi Nishiue |