日本地球惑星科学連合2022年大会

講演情報

[E] ポスター発表

セッション記号 S (固体地球科学) » S-CG 固体地球科学複合領域・一般

[S-CG43] スラブ内地震とその発生メカニズム

2022年6月2日(木) 11:00 〜 13:00 オンラインポスターZoom会場 (28) (Ch.28)

コンビーナ:北 佐枝子(建築研究所)、コンビーナ:大内 智博(愛媛大学地球深部ダイナミクス研究センター)、Manea Marina(Computational Geodynamics Laboratory, Geosciences Center, National Autonomous University of Mexico)、コンビーナ:大久保 蔵馬(防災科学技術研究所)、座長:北 佐枝子(建築研究所)、大内 智博(愛媛大学地球深部ダイナミクス研究センター)、大久保 蔵馬(防災科学技術研究所)、Marina Manea(Computational Geodynamics Laboratory, Geosciences Center, National Autonomous University of Mexico)

11:00 〜 13:00

[SCG43-P05] Deformation of metastable olivine under the conditions of Earth’s mantle transition zone: the role of olivine transformation on deep earthquakes

*松田 光平1大内 智博1肥後 祐司2丹下 慶範2 (1.愛媛大学地球深部ダイナミクス研究センター、2.高輝度光科学研究センター)


キーワード:深発地震、オリビン相転移、その場観察

The subduction zone produces a quite many of earthquakes which are divided into shallow (<40 km depth) earthquakes, intermediate-depth (>40 km) earthquakes and deep-focus (>300 km) earthquakes. The frequency of seismic activity becomes lower at greater depths due to the positive pressure dependency of frictional strength. Surprisingly, the frequency increases with depths at the depths in the mantle transition zone (e.g., Florich, 1989), suggesting that the mechanism of deep earthquakes is significantly different from that of shallow earthquakes. To investigate the mechanism of deep earthquakes, many experimental studies have been conducted using an analog material of germinate olivine at 1-2 GPa (Mg2GeO4: Green and Burnley, 1989) or fayalite at 4-9 GPa (Fe2SiO4: Officer and Secco, 2020). They reported that the olivine-spinel transformation under metastable condition could induce a faulting as a result of superplasticity due to grain size reduction along the fault. However, both germinate olivine and fayalite may not be an adequate analogue, because they directly transform to spinel phase and the amount of latent heat produced by their transformation reactions is much small than that for mantle olivine. Thus, we performed deformation experiments on metastable olivine at the pressures and temperatures of the mantle transition zone.
We conducted in-situ uniaxial deformation experiments on as-is olivine aggregates at pressures of 14-16 GPa and temperatures of 1050-1250 K with a constant displacement rate using a D-DIA apparatus at BL04B1/SPring-8. Pressure, stress, and strain were measured by using x-ray diffraction patterns and radiographs. Acoustic emissions (AEs) were also recorded by using six sensors during deformation, and the hypocenters of AEs were determined. Some off-line annealing experiments were also conducted at 15.5 GPa and temperatures of 950-1250 K using a D-DIA apparatus at GRC, Ehime Univ. Based on the results on annealing experiments, we estimated the lower limit temperature for nucleation of the high-pressure phases in ultrafine-grained domain such as fault gouge and damage zones.
We observed aseismic plastic deformation followed by faulting at temperatures ~1100 K. The faulting were terminated by an unstable slip, resulting in a blow-out. AEs were radiated around the timing of faulting. Microstructures of the recovered sample revealed that the fault gouge consists of nanoparticles of olivine, wadsleyite and a trace amount of platinum blobs, which are products of melting of the strain marker due to temperature ramping above 2200 K during the faulting. Off-line annealing experiments showed that the lower limit temperature for the nucleation of wadsleyite/ringwoodite in ultrafine-grained olivine aggregates is about 970 K, suggesting that the damage zone and gouge along the fault (i.e., pulverized domains) could be a preferential site for nucleation of wadsleyite/ringwoodite. Nucleation of such high-pressure phases may promote further grain size reduction of old olivine grains.