宜蘭平原及花東縱谷的測站為代表。而測站位於中央山脈區域的變質岩帶,整
參考文獻
Alford, R. (1986), Shear data in the presence of azimuthal anisotropy: Dilley Texas, paper presented at 1986 SEG Annual Meeting, Society of Exploration Geophysicists.
Angelier, J., J.-C. Lee, H.-T. Chu, J.-C. Hu, C.-Y. Lu, Y.-C. Chan, L. Tin-Jai, Y. Font, B.
t. Deffontaines, and T. Yi-Ben (2001), Le séisme de Chichi (1999) et sa place dans l'orogène de Taiwan, Comptes Rendus de l'Académie des Sciences-Series IIA-Earth and Planetary Science, 333(1), 5-21.
Bos, A. G., W. Spakman, and M. C. Nyst (2003), Surface deformation and tectonic setting of Taiwan inferred from a GPS velocity field, Journal of Geophysical Research:
Solid Earth (1978–2012), 108(B10).
Brocher, T. M., and N. I. Christensen (1990), Seismic anisotropy due to preferred mineral orientation observed in shallow crustal rocks in southern Alaska, Geology, 18(8), 737-740.
Campillo, M., and A. Paul (2003), Long-range correlations in the diffuse seismic coda, Science, 299(5606), 547-549.
Chang, C.-P., T.-Y. Chang, J. Angelier, H. Kao, J.-C. Lee, and S.-B. Yu (2003), Strain and stress field in Taiwan oblique convergent system: constraints from GPS observation and tectonic data, Earth and Planetary Science Letters, 214(1), 115-127.
Chang, E. T., W.-T. Liang, and Y.-B. Tsai (2009), Seismic shear wave splitting in upper crust characterized by Taiwan tectonic convergence, Geophysical Journal International, 177(3), 1256-1264.
Chen, Y. N., Y. Gung, S. H. You, S. H. Hung, L. Y. Chiao, T. Y. Huang, Y. L. Chen, W. T.
Liang, and S. Jan (2011), Characteristics of short period secondary microseisms (SPSM) in Taiwan: The influence of shallow ocean strait on SPSM, Geophysical Research Letters, 38(4).
Crampin, S. (1994), The fracture criticality of crustal rocks, Geophysical Journal
Letters, 86(15), 3447.
Hsu, Y.-J., S.-B. Yu, M. Simons, L.-C. Kuo, and H.-Y. Chen (2009), Interseismic crustal deformation in the Taiwan plate boundary zone revealed by GPS observations, seismicity, and earthquake focal mechanisms, Tectonophysics, 479(1), 4-18.
Huang, B. S., W. G. Huang, W. T. Liang, R. J. Rau, and N. Hirata (2006), Anisotropy beneath an active collision orogen of Taiwan: Results from across islands array observations, Geophysical research letters, 33(24).
Huang, T., Y. Chen, Y. Gung, L. Chiao, W. Liang, and S. Lee (2013), Resolving the crustal seismic anisotropy of Taiwan using ambient seismic noises, paper presented at AGU Fall Meeting Abstracts.
Johnston, J. E., and N. I. Christensen (1995), Seismic anisotropy of shales, Journal of Geophysical Research: Solid Earth (1978–2012), 100(B4), 5991-6003.
Kim, K.-H., J.-M. Chiu, J. Pujol, K.-C. Chen, B.-S. Huang, Y.-H. Yeh, and P. Shen (2005), Three-dimensional VP and VS structural models associated with the active subduction and collision tectonics in the Taiwan region, Geophysical Journal International, 162(1), 204-220.
Klosko, E., F. Wu, H. Anderson, D. Eberhart‐Phillips, T. McEvilly, E. Audoine, M.
Savage, and K. Gledhill (1999), Upper mantle anisotropy in the New Zealand region, Geophysical Research Letters, 26(10), 1497-1500.
Kuo‐Chen, H., F. T. Wu, D. Okaya, B. S. Huang, and W. T. Liang (2009), SKS/SKKS splitting and Taiwan orogeny, Geophysical Research Letters, 36(12).
Kuo‐ Chen, H., F. T. Wu, and S. W. Roecker (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 (1978–
2012), 117(B6).
Kuo, B. Y., C. C. Chen, and T. C. Shin (1994), Split S waveforms observed in northern Taiwan: implications for crustal anisotropy, Geophysical research letters, 21(14), 1491-1494.
Lewis, M. A., and P. Gerstoft (2012), Shear wave anisotropy from cross-correlation of seismic noise in the Parkfield pilot hole, Geophysical Journal International, 188(2), 626-630.
Lobkis, O. I., and R. L. Weaver (2001), On the emergence of the Green’s function in the correlations of a diffuse field, The Journal of the Acoustical Society of America, 110(6), 3011-3017.
Longuet-Higgins, M. S. (1950), A theory of the origin of microseisms, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences, 243(857), 1-35.
Mehta, K., R. Snieder, and V. Graizer (2007), Downhole receiver function: a case study, Bulletin of the Seismological Society of America, 97(5), 1396-1403.
Miyazawa, M., R. Snieder, and A. Venkataraman (2008), Application of seismic interferometry to extract P-and S-wave propagation and observation of shear-wave splitting from noise data at Cold Lake, Alberta, Canada, Geophysics, 73(4), D35-D40.
Nakata, N., and R. Snieder (2012), Estimating near‐surface shear wave velocities in Japan by applying seismic interferometry to KiK ‐ net data, Journal of Geophysical Research: Solid Earth (1978–2012), 117(B1).
Rau, R.-J., W.-T. Liang, H. Kao, and B.-S. Huang (2000), Shear wave anisotropy beneath the Taiwan orogen, Earth and Planetary Science Letters, 177(3), 177-192.
Schulz, L. (1949), A Direct Method of Determining Preferred Orientation of a Flat Reflection Sample Using a Geiger Counter X‐Ray Spectrometer, Journal of Applied Physics, 20(11), 1030-1033.
Shapiro, N. M., and M. Campillo (2004), Emergence of broadband Rayleigh waves from correlations of the ambient seismic noise, Geophysical Research Letters, 31(7).
Silver, P. G. (1996), Seismic anisotropy beneath the continents: Probing the depths of geology, Annual Review of Earth and Planetary Sciences, 24, 385-432.
Silver, P. G., and W. W. Chan (1991), Shear wave splitting and subcontinental mantle deformation, Journal of Geophysical Research: Solid Earth (1978–2012), 96(B10), 16429-16454.
Snieder, R. (2004), Extracting the Green’s function from the correlation of coda waves:
A derivation based on stationary phase, Physical Review E, 69(4), 046610.
Vauchez, A., and A. Nicolas (1991), Mountain building: strike-parallel motion and mantle anisotropy, Tectonophysics, 185(3), 183-201.
Wu, Y. M., C. H. Chang, L. Zhao, J. B. H. Shyu, Y. G. Chen, K. Sieh, and J. P. Avouac (2007), Seismic tomography of Taiwan: Improved constraints from a dense network of strong motion stations, Journal of Geophysical Research: Solid Earth (1978–
2012), 112(B8).
Wu, Y.-M., L. Zhao, C.-H. Chang, and Y.-J. Hsu (2008), Focal-mechanism determination in Taiwan by genetic algorithm, Bulletin of the Seismological Society of America, 98(2), 651-661.
Yu, S.-B., H.-Y. Chen, and L.-C. Kuo (1997), Velocity field of GPS stations in the Taiwan area, Tectonophysics, 274(1), 41-59.
Zatsepin, S. V., and S. Crampin (1997), Modelling the compliance of crustal rock—I.
Response of shear-wave splitting to differential stress, Geophysical Journal International, 129(3), 477-494.
何春蓀 (1982), 臺灣地體構造的演變, 台灣地質圖說明書, 經濟部中央地質調查所.
何春蓀 (1997), 臺灣地質概論-臺灣地質圖說明書, 經濟部中央地質調查所, 共 164 頁.
陳勇全 (2004), 六龜地區礫岩沈積環境與潮州斷層之研究.
附錄 A、各測站方位角修正值
SLG 2012/050 ~ 2012/275 163
附錄 B、各測站震波非均向性量測結果
圖 B-1、CHY 測站之震波非均向性量測結果。
圖 B-3、EGFH 測站之震波非均向性量測結果。
圖 B-4、ETLH 測站之震波非均向性量測結果。
圖 B-5、HGSD 測站之震波非均向性量測結果。
圖 B-7、HWA 測站之震波非均向性量測結果。
圖 B-8、ILA 測站之震波非均向性量測結果。
圖 B-9、LAY 測站之震波非均向性量測結果。
圖 B-11、NDT 測站之震波非均向性量測結果。
圖 B-12、NHDH 測站之震波非均向性量測結果。
圖 B-13、NMLH 測站之震波非均向性量測結果。
圖 B-15、NTC 測站之震波非均向性量測結果。
圖 B-16、NTS 測站之震波非均向性量測結果。
圖 B-17、NWL 測站之震波非均向性量測結果。
圖 B-19、PNG 測站之震波非均向性量測結果。
圖 B-20、RLNB 測站之震波非均向性量測結果。
圖 B-21、SLG 測站之震波非均向性量測結果。
圖 B-23、SNS 測站之震波非均向性量測結果。
圖 B-24、SSP 測站之震波非均向性量測結果。
圖 B-25、TAIB(H)測站之震波非均向性量測結果。
圖 B-27、WCHH 測站之震波非均向性量測結果。
圖 B-28、WDJ 測站之震波非均向性量測結果。
圖 B-29、WDLH 測站之震波非均向性量測結果。
圖 B-31、WHY 測站之震波非均向性量測結果。
圖 B-32、WJS 測站之震波非均向性量測結果。
圖 B-33、WLCH 測站之震波非均向性量測結果。
附錄 C、二十五萬分之一臺灣地質圖地層圖例
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