以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：77

、訪客IP：18.224.59.231

姓名	管卓康(Zhuo-Kang Guan)  查詢紙本館藏	畢業系所	地球科學學系
論文名稱	以多尺度地震儀陣列觀測，解析台灣西南部構造地震與地震層析成像 (Seismic tomography and seismicity of South-Western Taiwan by Multi-scale observations of dense seismic array)
檔案	[Endnote RIS 格式]    [Bibtex 格式]    [相關文章]   [文章引用]   [完整記錄]   [館藏目錄]   [檢視]  [下載] 本電子論文使用權限為同意立即開放。 已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。 請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。
摘要(中)	本研究使用多個短周期地震儀架設臨時的密集地震網，收集2020年中台灣西南部的地震資料，以及2016年美濃地震後的大量餘震資料，整合氣象局地震目錄及TAIGER的炸測數據等跨越空間與時間尺度的地震觀測資料，經過確實挑選與嚴格的篩選資料，透過有線差分法地震層析成象技術，計算出台灣西南部中尺度的精細速度模型，這個模型符合現有不同尺度的速度模型的共有特徵，在資料充足的地區，可通過水平與深度的6公里的棋盤格測試。根據新模型的定位結果，地震的群聚的現象比初始定位更加明顯，地震主要分布在$V_P$在5.2$km/s$的等值面以下，並重新演算的震源機制解，顯示出西部麓山帶以下5至10公里深的地震，主要由逆斷層與走向滑移的錯動型態，而且有區域分布上有明顯差異。藉由速度模型可以看整個研究區域的速度分布與地表地質分區有很強的相關性，北港高區的高速帶與西部鹿山帶的低速帶增厚，台南地區速度基盤最深可達15公里深，因此本研究所得的成果補足的過往觀測的尺度，並揭露出北港高區至台南盆地之間地震與波速變化特徵，這改進了大尺度速度模型對地質構造解析上的不足，對後續防災研究與盲斷層地震的調查提供更可信的基礎資料。
摘要(英)	This study provides a moderate-scale seismic tomography for detailing the resolve of southwest Taiwan, which involves two temporal short-period dense seismic arrays from the SW Taiwan investigation project in 2020, aftershocks monitoring of the Meinong earthquake in 2016, and cooperated external catalog between 2012 and 2019 from the Central weather bureau, and four shots data in the TAIGER project. Optimized hypocenter through new model reveals several concentrated distributed events and their new focal mechanism with thrust or strike-slip in 5 to 10 km depth under the West foothill. The resolution test of the 6-kilometer cube checkerboard resumed well, which means small structures resolving is possible. Our results correspond to main velocity features such as Peikang High and Tainan Basin very well to others′ regional-scale tomography. Furthermore, the local velocity perturbations along the deformation front and faults in the west foothill suggest the opportunity to involve tomography interpretation with the existing geology and geophysical evidence. Hence, the evolving of dense seismic arrays and renewed tomography provide the chance to access more detailed structures in depth such as blind faults, which are difficult to detect in the past.
關鍵字(中)	★ 地震層析成像 ★ 台灣西南部 ★ 高密度地震觀測陣列	關鍵字(英)	★ Seismic tomography ★ South-Western Taiwan ★ Dense seismic array
論文目次	1 緒論 1 1-1 研究動機 . 1 1-1-1 研究區域的獨特性 . 1 1-1-2 主要問題與預期成果 . 2 1-2 文獻回顧 . 3 1-2-1 區域地質背景 . 3 1-2-2 地震與地體構造研究 . 12 1-3 本文內容 . 15 2 資料與研究方法 18 2-1 地震資料 . 18 2-1-1 實驗設計的思路 . 18 2-1-2 儀器演進與比較 . 20 2-1-3 美濃2016地震觀測網 . 22 2-1-4 台灣西南部2020年地震觀測網 . 24 2-1-5 氣象局地震目錄 . 25 2-1-6 TAIGER . 29 2-2 資料處理與分析流程 . 30 2-2-1 波形管理、地震定位 — SEISAN . 30 2-2-2 走時層析成像 — FDTomo . 32 3 結果 52 3-1 地震定位 . 52 3-1-1 SW2020地震分布 . 52 3-1-2 美濃餘震分布 . 53 3-1-3 氣象局地震分布 . 54 3-2 震源機制解 . 54 3-3 地震層析成像 . 56 3-3-1 棋盤格測試 . 56 3-3-2 最終模型 . 57 4 討論 76 4-1 與現有模型比較 . 76 4-2 中尺度震測資料比對 . 77 4-3 台南盆地在陸上形貌 . 78 5 結論與展望 81
參考文獻	Aki, K. and Lee, W. H. K. (1976). Determination of three-dimensional velocity anomalies under a seismic array using first P arrival times from local earthquakes: 1. A homogeneous initial model. Journal of Geophysical Research, 81(23):4381–4399. Aki, K. and Richards, P. G. (2002). Quantitative Seismology. University Science Books, 2 edition. Angelier, J., Barrier, E., and Chu, H. T. (1986). Plate collision and paleostress trajectories in a fold-thrust belt: the foothills of taiwan. Tectonophysics, 125(1-3):161–178. Biete, C., Brown, D., Lund, B., Alvarez-Marron, J., Wu, Y.-M., Kuo-Chen, H., and Ho, C.-W. (2019). The influence of inherited continental margin structures on the stress and strain fields of the south-central taiwan fold-and-thrust belt. Geophysical Journal International, 219(1):430–448. Brown, D., Alvarez-Marron, J., Biete, C., Kuo-Chen, H., amanni, G., and Ho, C.-W. (2017). How the structural architecture of the eurasian continental margin affects the structure, seismicity, and topography of the south central taiwan fold-and-thrust belt. Tectonics, 36(7):1275–1294. Brown, D., Alvarez-Marron, J., Camanni, G., Biete, C., Kuo-Chen, H., and Wu, Y.-M. (2022). Structure of the south-central taiwan fold-and-thrust belt: Testing the viability of the model. Earth-Science Reviews, 231:104094. Brown, D., Alvarez-Marron, J., Schimmel, M., Wu, Y.-M., and Camanni, G. (2012). The structure and kinematics of the central taiwan mountain belt derived from geological and seismicity data. Tectonics, 31(5). Cerveny, V. (2001). Seismic Ray Theory. Cambridge University Press. Chan, C.-H., Ma, K.-F., Shyu, J. B. H., Lee, Y.-T., Wang, Y.-J., Gao, J.-C., Yen, Y.-T., and Rau, R.-J. (2020). Probabilistic seismic hazard assessment for taiwan: Tem psha2020. Earthquake Spectra, 36(1 suppl):137–159. Chen, C.-C. et al. (2005). 台東地區三維速度構造. Master’s thesis, National Central University. Chen, K.-X., Kuo-Chen, H., Brown, D., Li, Q., Ye, Z., Liang, W.-T., Wang, C.-Y., and Yao, H. (2016). Three-dimensional ambient noise tomography across the taiwan strait: The structure of a magma-poor rifted margin. Tectonics, 35(8):1782–1792. Ching, K.-E., Gourley, J. R., Lee, Y.-H., Hsu, S.-C., Chen, K.-H., and Chen, C.-L. (2016). Rapid deformation rates due to development of diapiric anticline in southwestern taiwan from geodetic observations. Tectonophysics, 692:241–251. Ching, K.-E., Rau, R.-J., Lee, J.-C., and Hu, J.-C. (2007). Contemporary deformation of tectonic escape in sw taiwan from gps observations, 1995–2005. Earth and Planetary Science Letters, 262(3-4):601–619. Hansen, P. C. (1992). Analysis of Discrete Ill-Posed Problems by Means of the L-Curve. SIAM Review, 34(4):561–580. Havskov, J., Voss, P. H., and Ottem ̈oller, L. (2020). Seismological observatory software: 30 yr of seisan. Seismological Research Letters, 91(3):1846–1852. Hole, J. and Zelt, B. (1995). 3-d finite-difference reflection traveltimes. Geophysical Journal International, 121(2):427–434. Hsu, Y.-J., Lai, Y.-R., You, R.-J., Chen, H.-Y., Teng, L. S., Tsai, Y.-C., Tang, C.-H., and Su, H.-H. (2018). Detecting rock uplift across southern taiwan mountain belt by integrated gps and leveling data. Tectonophysics, 744:275–284. Huang, H.-H., Wu, Y.-M., Song, X., Chang, C.-H., Kuo-Chen, H., and Lee, S.-J. (2014). Investigating the lithospheric velocity structures beneath the taiwan region by nonlin- ear joint inversion of local and teleseismic p wave data: Slab continuity and deflection. Geophysical Research Letters, 41(18):6350–6357. Huang, M.-H., B ̈urgmann, R., and Hu, J.-C. (2016a). Fifteen years of surface deformation in western taiwan: Insight from sar interferometry. Tectonophysics, 692:252–264. Huang, M.-H. and Evans, E. L. (2019). Total variation regularization of geodetically constrained block models in southwest taiwan. Journal of Geophysical Research: Solid Earth, 124(12):13269–13285. Huang, M.-H., Hu, J.-C., Ching, K.-E., Rau, R.-J., Hsieh, C.-S., Pathier, E., Fruneau, B., and Deffontaines, B. (2009). Active deformation of tainan tableland of southwestern taiwan based on geodetic measurements and sar interferometry. Tectonophysics, 466(3-4):322–334. Huang, M.-H., Tung, H., Fielding, E. J., Huang, H.-H., Liang, C., Huang, C., and Hu, J.- C. (2016b). Multiple fault slip triggered above the 2016 mw 6.4 meinong earthquake in taiwan. Geophysical Research Letters, 43(14):7459–7467. Jahn, B., Chi, W., Yui, T., et al. (1992). A late permian formation of taiwan (marbles from chia-li well no. 1): Pb-pb isochron and sr isotopic evidence, and its regional geological significance. Jour. Geol. Soc. China 35: 193-218. 84 Kan, L.-Y., Chevrot, S., and Monteiller, V. (2022). A consistent multiparameter Bayesian full waveform inversion scheme for imaging heterogeneous isotropic elastic media. Geophysical Journal International, 232(2):864–883. Kim, K.-H., Chiu, J.-M., Pujol, J., Chen, K.-C., Huang, B.-S., Yeh, Y.-H., and Shen, P. (2005). Three-dimensional vp and vs structural models associated with the active sub- duction and collision tectonics in the taiwan region. Geophysical Journal International, 162(1):204–220. Kuo, Y.-W., Wang, C.-Y., Kuo-Chen, H., Jin, X., Cai, H.-T., Lin, J.-Y., Wu, F. T., Yen, H.-Y., Huang, B.-S., Liang, W.-T., et al. (2016). Crustal structures from the wuyi-yunkai orogen to the taiwan orogen: The onshore-offshore wide-angle seismic experiments of the taiger and atsee projects. Tectonophysics, 692:164–180. Kuo-Chen, H., Chen, K.-X., Wei-Fang, S., Chun-Wei, H., Yuan-Hsi, L., Guan, Z.-K., Chu-Chun, K., and Wen-Yen, C. (2017). 3d vs ambient noise tomography of the 2016 m w 6.4 meinong earthquake source region in taiwan. TAO: Terrestrial, Atmospheric and Oceanic Sciences, 28(5):6. Kuo-Chen, H., Guan, Z.-K., Sun, W.-F., Jhong, P.-Y., and Brown, D. (2019). Aftershock sequence of the 2018 mw 6.4 hualien earthquake in eastern taiwan from a dense seismic array data set. Seismological Research Letters, 90(1):60–67. Kuo-Chen, H., Wu, F. T., and Roecker, S. W. (2012). Three-dimensional P velocity structures of the lithosphere beneath Taiwan from the analysis of TAIGER and related seismic data sets. Journal of Geophysical Research: Solid Earth, 117(B6):n/a–n/a. Liu, Q. and Gu, Y. (2012). Seismic imaging: From classical to adjoint tomography. Tectonophysics, 566:31–66. Lu, C.-H., Ni, C.-F., Chang, C.-P., Chen, Y.-A., and Yen, J.-Y. (2016). Geostatistical data fusion of multiple type observations to improve land subsidence monitoring resolution in the choushui river fluvial plain, taiwan. Terrestrial, Atmospheric & Oceanic Sciences, 27(4). Ma, K.-F., Wang, J.-H., and Zhao, D. (1996). Three-dimensional seismic velocity structure of the crust and uppermost mantle beneath taiwan. Journal of Physics of the Earth, 44(2):85–105. Omori, F. (1907). Preliminary note on the formosa earthquake of march 17, 1906. Bulletin of the Imperial Earthquake Investigation Committee, 1(2):53–69. Paige, C. C. and Saunders, M. A. (1982). Lsqr: An algorithm for sparse linear equations and sparse least squares. ACM Transactions on Mathematical Software (TOMS), 8(1):43–71. Rau, R.-J. and Wu, F. T. (1995). Tomographic imaging of lithospheric structures under taiwan. Earth and Planetary Science Letters, 133(3-4):517–532. Rawlinson, N., Pozgay, S., and Fishwick, S. (2010). Seismic tomography: A window into deep Earth. Physics of the Earth and Planetary Interiors, 178(3-4):101–135. Rawlinson, N. and Spakman, W. (2016). On the use of sensitivity tests in seismic tomography. Geophysical Journal International, 205(2):1221–1243. Roecker, S., Thurber, C., and McPhee, D. (2004). Joint inversion of gravity and arrival time data from parkfield: New constraints on structure and hypocenter locations near the safod drill site. Geophysical Research Letters, 31(12). Roecker, S., Thurber, C., Roberts, K., and Powell, L. (2006). Refining the image of the sanandreas fault near parkfield, california using a finite difference travel time computation technique. Tectonophysics, 426(1-2):189–205. Shearer, P. M. (2003). Introduction to Seismology. Journal of Seismology, 7(1):137–137. Tarantola, A. (2005). Inverse Problem Theory and Methods for Model Parameter Estimation. Society for Industrial and Applied Mathematics., Philadelphia. Tarantola, A. and Valette, B. (1982). Generalized nonlinear inverse problems solved using the least squares criterion. Rev. Geophys. Space Phys., 20(2):219–232. Vidale, J. (1988). Finite-difference calculation of travel times. Bulletin of the Seismological Society of America, 78(6):2062–2076. Wang, S. (1976). Erts-1 satellite imagery and its application in regional geologic study of southwestern taiwan. Petrol. Geol. Taiwan, 13:37–57. Wang, Y.-J., Chan, C.-H., Lee, Y.-T., Ma, K.-F., Shyu, J. B. H., Rau, R.-J., Cheng, C.-T., et al. (2016). Probabilistic seismic hazard assessment for taiwan. Terr. Atmos. Ocean. Sci., 27(3):325–340. Wen, S., Hsu, H.-J., Chang, W.-Y., and Chen, C.-H. (2012). A study of the seismogenic process beneath the south-western foothills in taiwan in relation with the 2010 jiasian earthquake. Tectonophysics, 570-571:57–64. Wen, S., Yeh, Y.-L., Chang, Y.-Z., and Chen, C.-H. (2017). The seismogenic process of the 2016 meinong earthquake, southwest taiwan. Terr. Atmos. Ocean. Sci, 28:651–662. Wu, F. T., Kuo-Chen, H., and McIntosh, K. (2014). Subsurface imaging, taiger experiments and tectonic models of taiwan. Journal of Asian Earth Sciences, 90:173–208. Wu, Y.-M., Chang, C.-H., Zhao, L., Shyu, J. B. H., Chen, Y.-G., Sieh, K., and Avouac, J.-P. (2007). Seismic tomography of taiwan: Improved constraints from a dense network of strong motion stations. Journal of Geophysical Research: Solid Earth, 112(B8). Yang, K., Ting, H., and Yuan, J. (1991). Structural styles and tectonic modes of neogene extensional tectonics in southwestern taiwan: implications for hydrocarbon exploration.Petrol. Geol. Taiwan, 26:1–31. 中國石油公司(1986). 嘉義地質圖. 中國石油公司(1989). 十萬分之一臺灣地質圖. 劉桓吉and 李錦發(1998). 雲林圖幅及說明書，五萬分之一臺灣地質圖. 原振維, 周錦德, 陳堯堂, 楊耿明, 陳雄茂, and 羅仕榮(1989). 台灣西部第三紀盆地演化與油 氣潛能之綜合評估(1/2), page 286. 經濟部七十八年度研究發展專題. 吉田要(1931). 所謂觸口山層. 2:27–29. 張麗旭, 周敏, and 陳培源(1947). 民國35年12月5日臺南之地震. 1:11–18. 徐明同(1985). 1935年以前之台灣歷史地震. pages 1–10. 1935年大地震紀念研討會論文集. 林啟文, 張徽正, 盧詩丁, 石同生, and 黃文正(2000a). 台灣活動斷層概論, volume 13. 經濟 部中央地質調查所特刊. 林啟文, 石同生, and 盧詩丁(2000b). 活動斷層調查報告-左鎮斷層. 活動斷層調查報告. 林欽仁(2020). 短週期陣列儀器測試報告, volume 29, pages 1–3. 台灣地震科學中心通訊. 胡潮昌(1987). 台南盆地之基盤構造與漸新世至中新世地層之研究, volume 24, pages 105–115. 石油季刊. 鄧屬予, 饒瑞鈞, 李錫堤, 劉家瑄, and 陳文山(2005). 台灣西南部斷層活動, volume 5. 西太平洋地質科學. 鄭世楠and 葉永田(1989). 西元1604年至1988年台灣地區地震目錄, volume IES-R-661. 中央研究院地球科學研究所. 鄭世楠, 葉永田, 徐明同, and 辛在勤(1999). 台灣十大災害地震圖集, volume CWB-9-1999-002-9. 中央氣象局. 鄭璟郁(2017). 利用噪聲成像解析嘉義梅山斷層區域之三維淺層剪力波速度構造. Master’s thesis, 國立中央大學. 黃旭燦(2003). 台灣中南部褶皺逆衝斷層帶地質構造特徵分析. PhD thesis, 國立中央大學. 黃立勝and 林其松(1981). 台南縣佳里一號探井地下地質報告, page 33. 中油公司內部報告. 黃鑑水, 張憲卿, and 劉桓吉(1994). 台灣南部觸口斷層地質調查與探勘, volume 9, pages 29–50. 經濟部中央地質調查所特刊.
指導教授	郭俊翔 郭陳澔(Chun‑Hsiang Kuo Hao Kuo-Chen)	審核日期	2023-8-17
推文	facebook   plurk   twitter   funp   google   live   udn   HD   myshare   reddit   netvibes   friend   youpush   delicious   baidu
網路書籤	Google bookmarks   del.icio.us   hemidemi   myshare