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研究生: 梅 慧 英
Hue-Anh Mai
論文名稱: The Post-rifting Subsidence History of the Nam Con Son Basin, Southwest South China Sea Margin
The Post-rifting Subsidence History of the Nam Con Son Basin, Southwest South China Sea Margin
指導教授: 葉孟宛
Yeh, Meng-Wan
李通藝
Lee, Tung-Yi
學位類別: 碩士
Master
系所名稱: 地球科學系
Department of Earth Sciences
論文出版年: 2015
畢業學年度: 103
語文別: 英文
論文頁數: 83
中文關鍵詞: Nam Con Son Basinsubsidence historypost-riftingSouthwest South China Sea
英文關鍵詞: Nam Con Son Basin, post-rifting, subsidence history, Southwest South China Sea
論文種類: 學術論文
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  • The Nam Con Son Basin (NCSB) is situated at the southwestern tip of the South China Sea (SCS), contains one of the highest hydrocarbon potential of the region due to unusual thick sequences. In order to decipher the cause of this unique feature, and its relationship to the regional tectonic evolution, plate reconstruction of SCS region is conducted via Gplates software (www.gplates.org). The reconstruction results indicated major tectonic events affecting the Nam Con Son Basin and SCS region are: (1) the opening of SCS (30-16 Ma), which coincides with the timing of rifting of the NCSB. (2) The collision of India to Eurasia induced rotation and escape of Indochina block along the Ailao Shan-Red River Fault (ASRR) since 28 Ma. The unusual thick sequence within NCSB was deposited during 16-10 Ma, which is post of the major tectonic events. To further evaluate the triggering mechanism, the tectonic subsidence curves are calculated from three wells (NCS-A, NCS-B, NCS-C) by backstripping analysis. By comparing the theoretical subsidence curve, the stretching factor (β) changed from > 2 during 16-10 Ma to ~ 1.5 during 10-5 Ma. Such large stretching factors are unusual for non rifting basin, which suggested another process such as supporting heat of magmatism might have contributed to the subsidence of the NCSB rather than strike-slip fault activity. Due to the record of magmatism this region and the difference of stretching factors within three wells, between the NCSB and the Cuulong Basin, we can assumed that the uniqueness of the NCSB are related to the post-rift magmatism in the SCS region.

    The Nam Con Son Basin (NCSB) is situated at the southwestern tip of the South China Sea (SCS), contains one of the highest hydrocarbon potential of the region due to unusual thick sequences. In order to decipher the cause of this unique feature, and its relationship to the regional tectonic evolution, plate reconstruction of SCS region is conducted via Gplates software (www.gplates.org). The reconstruction results indicated major tectonic events affecting the Nam Con Son Basin and SCS region are: (1) the opening of SCS (30-16 Ma), which coincides with the timing of rifting of the NCSB. (2) The collision of India to Eurasia induced rotation and escape of Indochina block along the Ailao Shan-Red River Fault (ASRR) since 28 Ma. The unusual thick sequence within NCSB was deposited during 16-10 Ma, which is post of the major tectonic events. To further evaluate the triggering mechanism, the tectonic subsidence curves are calculated from three wells (NCS-A, NCS-B, NCS-C) by backstripping analysis. By comparing the theoretical subsidence curve, the stretching factor (β) changed from > 2 during 16-10 Ma to ~ 1.5 during 10-5 Ma. Such large stretching factors are unusual for non rifting basin, which suggested another process such as supporting heat of magmatism might have contributed to the subsidence of the NCSB rather than strike-slip fault activity. Due to the record of magmatism this region and the difference of stretching factors within three wells, between the NCSB and the Cuulong Basin, we can assumed that the uniqueness of the NCSB are related to the post-rift magmatism in the SCS region.

    Acknowledgements i Abstract ii Table of contents iii List of tables v List of figures vi Chapter 1. Introduction 1 1.1. The uniqueness of the Nam Con Son Basin 1 1.2. Controlling factors on basin development 1 1.3. The stretching of the continental lithosphere 2 1.4. Objectives 6 Chapter 2. Geological setting 7 2.1. Tectonic setting 7 2.2. Basin development 9 Chapter 3. Material and methods 13 3.1. Plate reconstruction 13 3.1.1. Correlation of magmatism and the basin development 14 3.1.2. Application of Gplates software 17 3.2. Subsidence analysis 19 3.2.1. Subsidence from well information 19 3.2.2. Theoretical subsidence curves 26 3.2.3. Extensional measurements 26 Chapter 4. Results 27 4.1. Cenozoic plate reconstruction of SCS 27 4.1.1. Summary of Cenozoic magmatism across SCS 27 4.1.2. Summary major basins evolution around SCS 28 4.1.3. Correlation the magmatism and the development of basins around SCS 31 4.1.4. Gplates results 32 4.2. Subsidence results 42 4.2.1. Subsidence from well information 42 4.2.2. Theoretical subsidence curve 44 4.2.3. Extensional measurements 45 Chapter 5. Interpretation and Discussion 47 5.1. Significance of plate reconstruction results 47 5.2. The formation mechanism of thick post-rift sequence 51 Chapter 6. Conclusion 58 References 59 Appendix A. Magnetic anomaly data 67 Appendix B. The distribution of magmatism 68 Appendix C. Rotation file 72 Appendix D. Tectonically driven subsidence formula 73 Appendix E. Previous seismics in the NCSB 74 Appendix F. Back-stripping data 78

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