日本地球惑星科学連合2022年大会

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[J] ポスター発表

セッション記号 H (地球人間圏科学) » H-QR 第四紀学

[H-QR05] 地球惑星科学へのルミネッセンス・ESR年代測定の応用

2022年6月2日(木) 11:00 〜 13:00 オンラインポスターZoom会場 (14) (Ch.14)

コンビーナ:豊田 新(岡山理科大学理学部応用物理学科)、コンビーナ:田村 亨(産業技術総合研究所地質情報研究部門)、下岡 順直(立正大学地球環境科学部環境システム学科)、座長:豊田 新(岡山理科大学古生物学・年代学研究センター)、田村 亨(産業技術総合研究所地質情報研究部門)

11:00 〜 13:00

[HQR05-P01] 様々な深さでの断層の地震性すべりが石英のE1′ 中心に及ぼす影響

*田中 桐葉1武藤 潤1高橋 美紀2ジャワウィックラマ エランガ1、佐々木 理3、岡 壽崇4長濱 裕幸1 (1.東北大学大学院理学研究科地学専攻、2.産業技術総合研究所地質調査総合センター、3.東北大学総合学術博物館、4.日本原子力研究開発機構原子力科学研究所原子力基礎工学研究センター)


キーワード:高速摩擦、電子スピン共鳴、粒子粉砕、摩擦発熱、E1′ 中心、石英

A fault dating using electron spin resonance (ESR) is a developing method to estimate the age of the last fault movement. This method assumes that natural radiation-induced ESR intensity, which is proportional to the concentration of charges trapped in defects accumulated in the interseismic period, is completely reset due to fracturing, loading, and frictional heating by a seismic fault slip (Ikeya et al., 1982 Science). This is called ESR signal zeroing, and the incomplete zeroing can result in age overestimation, hence, the deep understanding of the mechanism and conditions for complete/incomplete zeroing is required. We have performed high-velocity friction (HVF) experiments under various normal stresses to investigate the possibility for the signal zeroing by seismic fault slips at various depths. Moreover, to reveal factors enhancing/impeding the signal zeroing, we conducted microstructural observations on the experimental products and temperature estimations within the gouges during the HVF experiments.
HVF experiments were performed for coarse-grained, synthetic quartz grains as the starting material, at an equivalent slip rate of 1 m/s, normal stresses (σ) of 1–3 MPa, and displacements (Deq) of 10–40 m. ESR measurements to detect the E1′ center in quartz (≡Si, where − is an electron pair and is an unpaired electron) were conducted for the starting material and simulated-fault gouges. We observed the microstructures of the starting material and gouges using a scanning electron microscope (SEM). The temperature within the gouges during experiments was measured by the thermocouple located at the gouge surface and estimated by finite element method (FEM) with COMSOL Multiphysics.
In the HVF experiments at σ = 1 MPa, the ESR intensity of the E1′ center tended to increase with displacements and were more than 2 orders of magnitudes higher than that of the starting material. In this series of HVF experiments, the maximum temperature estimated by FEM modelling, which was consistent with the measured temperature, was dependent on displacements. Up to Deq = 30 m, the maximum temperature in the gouges was estimated to be about 250°C. At Deq = 40 m, the estimated temperature reaches 300–500°C due to significant frictional heating. Even though the E1′ center is generally thermally unstable above about 200–300°C (e.g., Toyoda and Ikeya, 1991 Geochem. J.), the ESR intensities increased in all of these experiments. It indicates that grain fracturing effect on the E1′ center was more dominant than frictional heating effect for cases at σ = 1 MPa as shown in the results that grain fracturing during the low-velocity friction increases the intensity of the E1′ center (Tanaka et al., 2021 Geochronometria).
In the HVF experiments at σ = 2, 3 MPa, the ESR intensity of the E1′ center only increased by 1 order of magnitude compared to that of the starting material. SEM observations on the experimental products indicated more significant grain size reduction than those of the HVF experiments at σ = 1 MPa. Thus, ESR intensity was weakened contrary to our expectation that grain fracturing effect would impede the ESR signal zeroing as shown in cases at σ = 1 MPa. The FEM modeling showed that small sections near the friction surfaces in the gouges were over 500°C within ten seconds in the experiment. The intensity of the E1′ center is generally completely zeroed by heating at 500°C or higher within a few ten seconds (e.g., Hataya and Tanaka, 1997 CRIEPI Report). Hence, frictional heating effect began to be predominant at σ = 2, 3 MPa. Locally high temperature over 500°C in the gouge zone might play a role to reduce the ESR intensity partly and yield incomplete ESR signal zeroing.
From these results, it could be concluded that ESR signal zeroing mechanism of the E1′ center by high-velocity frictional slip is not simple, but a competition between two opposite effects, grain fracturing and frictional heating, controls the ESR intensity.