臺灣東北部外海的震測地層學與正斷層構造分析

許綪洧; Chien-Wei Hsu

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/96943

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張日新	zh_TW
dc.contributor.advisor	Jih-Hsin Chang	en
dc.contributor.author	許綪洧	zh_TW
dc.contributor.author	Chien-Wei Hsu	en
dc.date.accessioned	2025-02-25T16:09:44Z	-
dc.date.available	2025-02-26	-
dc.date.copyright	2025-02-25	-
dc.date.issued	2025	-
dc.date.submitted	2025-02-10	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/96943	-
dc.description.abstract	臺灣北方海域隨著臺灣造山帶逐漸向南遷移，自碰撞造山進入由伸張系統主導的垮山階段，而形成了一系列東北西南向的正斷層系統。為更深入了解臺灣北方海域正斷層系統於垮山時期之構造特徵及其發育過程，本研究將利用臺灣東北外海已發表的剖面、重新處理的剖面和新收集的多頻道反射震測資料，對正斷層分布進行重新檢視，同時利用各斷層滑移量隨時間的分布變化對正斷層進行構造分析，以了解斷層在生長過程各階段的活動性，並有助斷層是否具備持續延伸的潛勢評估。本研究透過震測資料辨識出三個層序邊界（盆地基盤面PRSB及上覆層序中的PU1及PU2），以及九個主要的東北西南向正斷層（外山腳斷層1、外山腳斷層2、外崁腳斷層、外基隆斷層2、外基隆斷層1、外台北斷層、外龍洞斷層、外蚊子坑斷層以及外三貂角斷層），並藉由三個層序邊界的構造等時圖，劃分出陸棚區、近岸斷塊區、離岸地塹區及地塹以東地區共四個構造區。再透過正斷層之滑移量-斷層跡線距離（T-x）等構造分析，我們發現九條斷層發育以南遷為主（外山腳斷層2、外崁腳斷層、外基隆斷層2、外基隆斷層1、外台北斷層、外龍洞斷層），少部分原位（in situ）發展（外山腳斷層1、外三貂角斷層），亦有少部分往北向發展（外蚊子坑斷層）。本研究區域構造演化可劃分為四個階段。第一階段（2.6 Ma之前）處於壓縮系統主導的逆斷層構造環境；第二階段（2.6 Ma之後）時轉為伸張系統，造成PRSB開始沉降且臺灣北方海域轉為正斷層系統開始發展；第三階段（約2 1 Ma）或因沖繩海槽再次向西延伸，產生新一期斷層活動並形成PU1，此期正斷層活動較前期趨緩；第四階段（1 Ma至今）為最晚近期火山活動，正斷層活動再次活躍，形成PU2並呈現明顯的南向遷移趨勢。然而關於正斷層發育的精確時序，仍需更多近岸海域地層年代與分布以進一步進行驗證與討論。	zh_TW
dc.description.abstract	The collapsed orogenic belt in northern Taiwan experienced stress changes from a compressional to an extensional environment, showing a series of normal fault structures offshore northern Taiwan. To better understand the structural features and development of the normal fault system, we revisit the distribution of offshore normal faults by newly collected multi-channel seismic (MCS) reflection data, combined with published and reprocessed archived MCS profiles northern offshore Taiwan. Furthermore, we take advantage of structural analyses on the basis of the fault throw distribution over time to understand fault activities in each stage and to estimate the possible future extension of these faults. In our seismic dataset, 3 seismic sequence boundaries(the lowermost PRSB, and PU1 and PU2 within the overlying sequence) and along with 9 major NE–SW-trending normal faults including Outer Shanchiao Fault 1 (OSAC1), Outer Shanchiao Fault 2 (OSAC2), Outer Kanchiao Fault (OKAC), Outer Chilung Fault 2 (OCHG2), Outer Chilung Fault 1 (OCHG1）, Outer Taipei Fault (OTP), Outer Longdong Fault (OLD), Outer Wentzukeng Fault (OWTK), and Outer Sandiaojiao Fault (OSDJ). Based on the structural contour map of the seismic sequence boundaries, 4 distinct structural regions are recognized, including the Shelf Zone, the Nearshore Fault Blocks area, the Offshore Graben area, and the East of the Graben. The fault throw to distance along the fault trace plots (T-x plot) reveal that most of the observed faults migrated southward (OSAC2, OKAC, OCHG2, OCHG1, OTP, OLD). Only few faults developed in situ (OSAC1 and OSDJ) and one (OWTK) migrated northward. Then, a 4-stage tectonic evolution model of the northern off Taiwan is proposed. The first stage (2.6 Ma~) was characterized by a compressional regime and associated reverse fault structures. In the second stage (after 2.6 Ma), the stress regime changed from compression to extension, resulting in the PRSB to subside and the normal fault system in the northern offshore Taiwan to initiate. During 2–1 Ma, northern offshore Taiwan was influenced by westward extension of the Okinawa Trough, leading to a new phase of faulting and the formation of PU1; however, fault activities during the third stage were more reduced than previous stages. The fourth stage (1 Ma to present) was marked by the most recent volcanic activities and reactivated normal faults, showing a pronounced trend of southward migration. However, the precise ages of normal fault development remain uncertain and future investigation of the nearshore stratigraphic distributions are required.	en
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dc.description.tableofcontents	口試委員會審定書 i 誌謝 ii 中文摘要 iii 英文摘要 iv 目次 vi 圖次 x 表次 xiv 第一章緒論 1 1.1 臺灣北方海域的大地架構與地質構造 1 1.2 臺灣北方海域正斷層 3 1.3 正斷層系統的發展與分析 6 1.4 研究動機與目的 12 第二章地質架構 14 2.1 臺灣東北部陸域地質架構 14 2.1.1 臺灣東北部地層 14 2.1.2 臺灣東北部陸域斷層 16 2.1.3 臺灣東北部陸域火山群 21 2.2 臺灣東北海域地質架構 26 2.2.1 海域地層 26 2.2.2 海域地形 32 2.2.3 海域斷層 34 2.2.4 臺灣北方海域火山分布 42 2.3 臺灣北部地體架構演化 43 2.3.1 原臺灣造山帶（臺灣新畿褶皺帶南段） 45 2.3.2 後造山垮塌 48 2.3.3 沖繩海槽南段 48 第三章材料與方法 51 3.1 研究方法 51 3.2 震測資料處理步驟 58 3.3 不整合面之定義與參照 63 3.4 構造等時圖與沉積物厚度圖繪製 65 3.5 正斷層生長分析 66 3.5.1 斷層滑移量分析圖繪製 67 3.5.2 分析方法的不確定性及二維震測資料的限制 70 第四章結果 71 4.1 震測地層學分析及解釋 71 4.1.1 震測層序邊界 71 4.1.2 震測層序與震測相 72 4.2 多頻道反射震測剖面之展示 75 4.2.1 剖面A 75 4.2.2 剖面B 76 4.2.3 剖面C 78 4.3 構造等時圖（Structural Contour Map） 89 4.3.1 PRSB 89 4.3.2 PU1 90 4.3.3 PU2 90 4.4 沉積物厚度圖之結果（Isochron Map） 93 4.5 正斷層分析之結果 95 4.5.1 滑移量與斷層跡線距離的散布圖（△T-x plot） 95 4.5.2 累積滑移量與斷層跡線距離的散布圖（T-x plot） 102 第五章討論 104 5.1 震測層序邊界之年代 104 5.2 構造區域之劃分 107 5.2.1 陸棚區 107 5.2.2 近岸斷塊區 107 5.2.3 離岸地塹區 108 5.2.4 地塹以東地區 108 5.3 正斷層活動性 110 5.4 正斷層系統發育 116 5.4.1 正斷層發育中心變遷 116 5.4.2 正斷層與半地塹盆地發育之關聯 130 5.5 海域正斷層系統之發展與陸域逆斷層系統之關聯 135 5.6 區域構造演化歷史 137 第六章結論 140 參考文獻 142	-
dc.language.iso	zh_TW	-
dc.subject	造山垮塌	zh_TW
dc.subject	臺灣北方海域	zh_TW
dc.subject	多頻道反射震測	zh_TW
dc.subject	斷層滑移量	zh_TW
dc.subject	山腳斷層	zh_TW
dc.subject	orogenic collapse	en
dc.subject	offshore northeastern Taiwan	en
dc.subject	multi-channel seismic data	en
dc.subject	fault throw	en
dc.subject	Shanchiao Fault	en
dc.title	臺灣東北部外海的震測地層學與正斷層構造分析	zh_TW
dc.title	Seismic Stratigraphy and Normal Fault Structural Analysis Offshore Northeastern Taiwan	en
dc.type	Thesis	-
dc.date.schoolyear	113-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	鄧屬予;陳文山;劉家瑄;楊耿明	zh_TW
dc.contributor.oralexamcommittee	Louis Suh-Yui Teng;Wen-Shan Chen;Char-Shine Liu;Kenn-Ming Yang	en
dc.subject.keyword	臺灣北方海域,多頻道反射震測,斷層滑移量,山腳斷層,造山垮塌,	zh_TW
dc.subject.keyword	offshore northeastern Taiwan,multi-channel seismic data,fault throw,Shanchiao Fault,orogenic collapse,	en
dc.relation.page	154	-
dc.identifier.doi	10.6342/NTU202500594	-
dc.rights.note	同意授權(限校園內公開)	-
dc.date.accepted	2025-02-11	-
dc.contributor.author-college	理學院	-
dc.contributor.author-dept	海洋研究所	-
dc.date.embargo-lift	2030-02-10	-
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