日本地球惑星科学連合2015年大会

講演情報

ポスター発表

セッション記号 S (固体地球科学) » S-TT 計測技術・研究手法

[S-TT52] 空中からの地球計測とモニタリング

2015年5月27日(水) 18:15 〜 19:30 コンベンションホール (2F)

コンビーナ:*楠本 成寿(富山大学大学院理工学研究部(理学))、大熊 茂雄(産業技術総合研究所地質情報研究部門)、光畑 裕司(独立行政法人 産業技術総合研究所)、小山 崇夫(東京大学地震研究所)

18:15 〜 19:30

[STT52-P04] Three-dimensional resistivity modelling of GREATEM survey data from the Nojima Fault, Awaji Island, south-east Japan.

*ALLAH, Sabry ABD1Toru MOGI1Hisatoshi ITO2Akira JOMORI3Youichi YUUKI4Elena FOMENKO5Kenzo KIHO2Hideshi KAIEDA2Koichi SUZUKI2Kazuhiro TSUKUDA2 (1.Institute of Seismology and Volcanology, Hokkaido University、2.Civil Engineering Research Laboratory, Central Research Institute of Electrical Power Industry、3.NeoScience Co., 5-11-22 Osato, Sennan, Osaka, 590-0526, Japan、4.Geotechnical Center, Oyo Co., 2-61-5 Toro, Saitama, 331-8688, Japan.、5.Faculty of Computational Mathematics and Cybernetics, Lomonosov Moscow State University, Moscow)

キーワード:3D EM forward modeling, GREATEM, Numerical approximations, Airborne Electromagnetic, Fault zone survey

An airborne electromagnetic (AEM) survey using the grounded electrical-source airborne transient electromagnetic (GREATEM) system was conducted over the Nojima Fault on Awaji Island, south-east Japan, to assess GREATEM survey applicability for studying coastal areas with complex topographic features. To obtain high-quality data with an optimised signal-to-noise ratio, a series of data processing techniques was used to acquire the final transient response curves from the field survey data.
The 1D inversion results were feasible in that the horizontal resistivity contrast was not much higher than the true contrast, but they were not reasonable in that the horizontal resistivity values were greatly changed. To circumvent this problem, we performed numerical forward modelling using a finite-difference staggered-grid method (Fomenko and Mogi, 2002) adding a finite-length electrical dipole source routine to generate a three-dimensional (3D) resistivity structure model from GREATEM survey data of the Nojima Fault area. The 3D model was based on an initial model consisting of two adjacent onshore and offshore layers of different conductivity such that, a highly conductive sea of depth (10?40 m) is placed on top of a uniform half-space, assuming the presence of topographic features on the inland side. We examined the fit of the magnetic transient responses between field data and 3D forward-model computed data, the latter were convolved with the measured system response of the corresponding dataset. The inverted 3D resistivity structures showed that the GREATEM system has the capability to map underground resistivity structures as deep as 500 m onshore and offshore. The GREATEM survey delineated how seawater intrudes on the land side of the fault and indicated that the fault is a barrier to seawater invasion.