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研究生: 李東翰
Dung-Han Lee
論文名稱: 台灣東部海岸山脈熔積岩產狀與年代學之研究
Occurrence and geochronology of peperites in the Coastal Range, eastern Taiwan
指導教授: 賴昱銘
Lai, Yu-Ming
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: 2020
畢業學年度: 108
語文別: 中文
論文頁數: 129
中文關鍵詞: 海岸山脈火山島弧火山岩相熔積岩鋯石鈾鉛定年
英文關鍵詞: Coastal Range, Volcanic arc, Volcanic lithofacies, Peperite, Zircon U-Pb dating
DOI URL: http://doi.org/10.6345/NTNU202001051
論文種類: 學術論文
相關次數: 點閱:185下載:39
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  • 熔積岩為熱的岩漿物質與未固結的沉積物交互作用所形成的產狀,為一個良好的定年材料。前人文獻指出在海岸山脈中的熔積岩只存在於陸上環境,且為火山碎屑流所形成,但經由重新檢視熔積岩之定義,只要火山產物能保存其熱能,在水下環境也能產生熔積岩,大部分的國外文獻所判視的熔積岩是於含水環境形成。因此本研究利用沉積物流體化、岩象學等其他熔積岩的證據,在海岸山脈中有七個區域發現熔積岩,分別為:嶺頂、砂脈橋、月洞遊憩區、膽曼海岸、泰源隧道、馬武窟溪及七里溪等剖面,對各區域熔積岩的組合、種類與形成機制進行相關的探討,並針對馬武窟溪與七里溪區域熔積岩中的火山碎屑進行鋯石鈾鉛定年,藉此找尋海岸山脈南段火山頂層的噴發年代。
    研究結果顯示熔積岩由白色或黑色火山碎屑與凝灰質或鈣質的沉積岩所組成,這些組合中具有凝灰質砂岩的熔積岩可以視為火山島弧已成長至水面上的指標。熔積岩的種類除了砂脈橋與泰源隧道區域為流體狀熔積岩,其餘皆為塊狀與流體狀熔積岩同時出現,流體狀熔積岩的出現表示熔積岩的生成環境為含水環境,由此可知海岸山脈熔積岩形成於任意含水環境。海岸山脈熔積岩形成機制,不只是前人所述火山碎屑流,岩漿淺層侵入、熔岩流所形成的熔積岩也都有出露。
    成廣澳火山與都蘭山火山的範圍內的熔積岩位在石梯坪凝灰岩層與八里灣層的交界處,熔積岩鋯石鈾鉛定年結果為:成廣澳火山頂層噴發年代為6.3± 0.4 Ma、都蘭山火山頂層噴發年代為6.3± 0.3 Ma及6.8± 0.3 Ma,表示說這兩座火山島約在6 Ma時就已經成長超出水面了。成廣澳火山的樣本中發現大量的繼承鋯石,年代統計為214± 3 Ma,呼應前人所提出的在東台灣火山噴發時有抓取到古老陸塊的鋯石。都蘭山火山頂層噴發年代相較於前人的年代結果年輕了約2 Ma,透過分別計算鋯石核心與邊緣年代,發現有數顆鋯石有顯著的年代變化,鋯石邊緣的年代落在5-7 Ma,其中年代5 Ma的鋯石不在少數,可能表示有更年輕的噴發年代。

    Peperite is an occurrence formed by hot magmatic materials such as magma, lava flow, and pyroclastic flow interaction with unconsolidated sediments. Previous account peperite is a good material for dating age. According to previous studies have found the peperite in the Coastal Range, eastern Taiwan. Peperite in volcanic arc succession and only exists in the subaerial environment formed by pyroclastic flows. However, review the definition of peperite, it can also exist in the subaqueous environments as long as the heat can be preserved in the hot magmatic materials. Further most foreign studies identified that the peperite is form in subaqueous environment. This study used sedimentary fluidization and petrological evidence to recognize the peperite in the Coastal Range, eastern Taiwan. Peperite can be found in seven outcrops: Lingding, Sand Dike Bridge, Yuedong, Danman, Taiyuan Tunnel, Mawukuchi and Chilichi. Describe the combination and types of the peperite in each outcrop. and zircon U-Pb age results for selected outcrops were also discussed in this study.
    Peperite are composed of white and black volcanic clasts with tuffaceous sandstone and calcareous sedimentary rocks. The peperite with tuffaceous sandstone can be regarded as an indicator that the volcanic arc has grown to sea level. Except that the areas of Sand Dike Bridge and Taiyuan Tunnels are fluidal peperite, occurrences in the other outcrops show both blocky and fluidal peperite. These fluidal peperite must formed in subaqueous environment, thus, peperite in the Coastal Range were not only exist in the subaerial eruptive facies but also in some subaqueous environment. Based on the relations between peperite and the surrounding lithofacies, the juvenile clasts which were formed peperite can be identified as the shallow magma intrusion, lava flow and pyroclastic flow in Mawukuchi, Yuedong and Lingding, respectively.
    Peperite in Mawukuchi and Chilichi are exposed at the junction between Tuluanshan Formation (Shitiping tuff) and Paliwan Formation young zircon U-Pb dating result yield a mean age of 6.3 ± 0.4 Ma in the Mawukuchi area and is similar to the previous results. However, a large number of inherited zircons can be found in this sample with a Cathaysian-type ages as the signal shows in Chimei and Lanyu volcanos. This result prove that the old continental fragment must have overlain the Luzon subduction zone and that inherited zircons were picked up during the ascent of magma to the magma chamber. Two peperite samples got zircon U-Pb dating results of 6.3± 0.3 Ma and 6.8± 0.3 Ma in the Chilichi area. Both of these ages are younger than the previous work (8.5± 0.2 Ma). These igneous zircons with ages from 7 to 5 Ma in the rim, and the amount of 5 Ma zircon isn’t less than other. So this result indicate that the Tuluanshan volcano may still have volcanism during 5 to 6 Ma.

    誌謝 i 中文摘要 ii 英文摘要 iii 目錄 vi 圖目 ix 表目 xv 第一章、緒論 1 1.1引言 1 1.2.前人研究 3 1.2.1熔積岩定義與組成 3 1.2.2熔積岩分類 6 1.2.3海岸山脈中的熔積岩 8 1.3研究動機與目的 10 第二章、地質背景 11 2.1地層概述 11 2.2火山體研究 13 2.3火山島弧噴發年代 15 第三章、研究方法 18 3.1熔積岩辨認方法 18 3.1.1野外調查 18 3.1.2岩象學證據 20 3.2熔積岩之特徵及野外岩相觀察 21 3.3鋯石鈾鉛定年 21 3.3.1樣本分析前處理 22 3.3.2儀器與分析 23 第四章、研究結果 25 4.1嶺頂 27 4.1.1熔積岩證據 27 4.1.2熔積岩之特徵 32 4.1.3周圍的岩相 33 4.2砂脈橋 35 4.2.1熔積岩證據 36 4.2.2熔積岩之特徵 39 4.2.3周圍的岩相 39 4.3月洞遊憩區 41 4.3.1熔積岩證據 42 4.3.2熔積岩之特徵 45 4.3.3周圍的岩相 46 4.4膽曼海岸 48 4.4.1熔積岩證據 48 4.4.2熔積岩之特徵 52 4.4.3周圍的岩相 53 4.5泰源隧道 54 4.5.1熔積岩證據 54 4.5.2熔積岩之特徵 58 4.5.3周圍的岩相 59 4.6馬武窟溪 61 4.6.1熔積岩證據 62 4.6.2熔積岩之特徵 66 4.6.3周圍的岩相 68 4.6.4鋯石鈾鉛定年結果 71 4.7七里溪 74 4.7.1熔積岩證據 75 4.7.2熔積岩之特徵 78 4.7.3周圍的岩相 79 4.7.4鋯石鈾鉛定年結果 82 第五章、討論 86 5.1海岸山脈熔積岩特徵 86 5.1.1熔積岩出露地點不一致 86 5.1.2熔積岩的組成 90 5.1.3熔積岩的種類 91 5.2海岸山脈熔積岩形成機制 94 5.2.1嶺頂區域 94 5.2.2月洞遊憩區區域 99 5.2.3馬武窟溪區域 103 5.3海岸山脈南段鋯石年代意義 106 5.3.1馬武窟溪中的繼承鋯石 106 5.3.2都蘭山火山的頂層噴發年代 110 第六章、結論 111 參考文獻 113 附錄表 124 附錄一、凝灰質砂岩含玻屑、晶體及岩屑分布圖 124 附錄二、馬武窟溪鋯石鈾鉛定年全數據 125 附錄三、七里溪鋯石鈾鉛定年全數據CLC01 126 附錄四、七里溪鋯石鈾鉛定年全數據CLC02 127 附錄五、七里溪鋯石核心與邊緣年代全數據 128

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