從礦脈中液包體重建臺灣廬山地熱區之熱液歷史

王奕晴; Yi-Ching Wang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101767

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	宋聖榮	zh_TW
dc.contributor.advisor	Sheng-Rong Song	en
dc.contributor.author	王奕晴	zh_TW
dc.contributor.author	Yi-Ching Wang	en
dc.date.accessioned	2026-03-04T16:24:23Z	-
dc.date.available	2026-03-05	-
dc.date.copyright	2026-03-04	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-23	-
dc.identifier.citation	王詠絢 (1999) 臺灣島弧火成岩伴生金屬礦床之液包體研究。國立臺灣大學地質學研究所博士論文，共166頁。朱瑞鼎 (1999) 從十八重溪層岩脈中液包體推論台灣雪山山脈南部岩層變形時之溫壓狀況。國立臺灣大學地質學研究所碩士論文，共103頁。李元希、楊昭男 (1994) 大禹嶺地區地質構造的演化。經濟部中央地質調查所彙刊，第9號，第77-105頁。何春蓀 (1975) 臺灣地質概論：臺灣地質圖說明書。經濟部中央地質調查所。何春蓀 (1987) 中央山脈西翼及脊樑山脈區的地質。地工技術雜誌，第19期，第81-90頁。涂家綸、李振維、李昇祐、周柏緯、林昰瑞、宋聖榮 (2024) 南投縣廬山地熱區構造分析。中華民國地質學會與中華民國地球物理學會113年暨學術研討會摘要集，第323頁。曹恕中 (1996) 臺灣中央山脈變質沉積岩伊萊石結晶度、鋯石核飛跡年代和鉀氬年代之地質意義。國立臺灣大學地質學研究所博士論文。張寶堂、焦中輝 (1979) 廬山地熱區之地質。鑛冶，第23卷，第2期，65-72。陳宇淮 (2016) 臺灣宜蘭三星地下岩芯之液包體研究。國立臺灣海洋大學應用地球科學研究所，共124頁。陳曉玉 (2005) 埔里至廬山地區鋯石核飛跡定年研究。國立中正大學應用地球物理研究所碩士論文，共54頁。程正 (1993) 以液包體與熱螢光技術探討屏風山地區金礦礦化作用與探勘的可行性。國立成功大學地球科學系碩士論文。湯守立 (1989) 臺灣中央山脈大禹嶺地區石英脈與節理的構造分析。國立臺灣大學地質學研究所碩士論文，共108頁。宋聖榮、羅偉、葛岳淵、王祈、盧乙嘉 (2024) 地下三維地質模型建置-南投縣廬山地區期中報告。經濟部地質調查及礦業管理中心，共91頁。廖珙含 (2011) 台灣中部橫貫公路大禹嶺地區石英脈發育之研究。國立臺北科技大學資源工程研究所碩士論文，共85頁。盧煥章 (1990) 流體-熔體包裹體。地球化學，第3期，第225-229頁。 Bodnar, R. J. (1993). Revised equation and table for determining the freezing point depression of H2O-NaCl solutions. Geochimica et Cosmochimica Acta, 57, 683-684. Bodnar, R. J. (2003). Reequilibration of fluid inclusions. In I. Samson, A. Anderson, & D. Marshall, eds. Fluid inclusions: Analysis and interpretation. Mineral. Assoc. Canada, 32, 213-230. Bodnar, R. J., Vityk, M. O., (1994). Interpretation of microthermometric data for H2O–NaCl fluid inclusions. Fluid inclusions in minerals, methods and applications, 117-130. Chi, G., Diamond, W.L., Lu, H., Lai, J. and Chu, H., (2021). Common problems and pitfalls in fluid inclusion study: A review and discussion. Minerals, 11(7), 23. Collins, P. L. F., (1979). Gas hydrates in CO2-bearing fluid inclusions and the use of freezing data for estimation of salinity. Economic Geology,74, 1435-1444. Crawford, M. L. and Hollister, L. S., (1986). Metamorphic fluids: The evidence from fluid inclusions. 35. Darling, R. S., (1991). An extended equation to calculate NaCl contents from final clathrate melting temperatures in H2O-CO2-NaCl fluid inclusions: Implications for P-T isochore location. Geochimica at Cosmochimica Acta, 55, 3869-3871. Engelder, T., (1985). Loading paths to joint propagation during a tectonic cycle: an example from the Appalachian Plateau, U.S.A. Journal of Structural Geology, 7(3–4), 459-476. Hall, D. L., Sterner, S. M. and Bodnar, R. J., (1999). Freezing point depression of NaCl-KCl-H2O solutions. Economic Geology, 83, 197-202. Hancock, P. L., (1985). Brittle microtecronics: principles and practice. Journal of Structural Geology, 7, 437-458. Hurai, V., Huraiova, M., Slobodnik, M. and Thomas, R., (2015). Geofluids: Developments in microthermometry, spectroscopy, thermodynamics, and stable isotopes. Elsevier. Kalyuzhnyi, V. A. and Koltun, L. I., (1953). Some data on pressures and temperatures during formation of minerals in Nagol’nyy Kryazh, Donets Basin. Minerals Sborink Lvov Geological Obshch, 7, 67-74. Liu, T. K., (1982). Tectonic implication of fission track ages from the Central Range, Taiwan, Proceedings of the Geological Society of China,25, 22-37. Phillips, W. J. (1974). The development of vein and rock textures by tensile strain crystallization. Journal of the Geological Society of London, 130, 441-448. Potter, R.W., (1977). Pressure corrections for fluid-inclusions homogenization temperatures based on the volumetric properties of the system NaCl-H2O. Journal of. Research U.S. Geological Survey, 5, 603-607. Ramsay, J. G., (1980). The crack-seal mechanism of rock deformation. Nature, 284. Roedder, E.(1984). Fluid inclusions: Reviews in Mineralogy. Virginia: Mineralogical Society of America, 12, 644. Roedder, E. and Bodnar, R. J. (1980). Geolgic pressure determinations from fluid inclusion studies. Annual Review of Earth and Planetary Sciences, 8, 263-301. Shepherd, T. J., Rankin, A. H., Alderton, D. H. M., (1985). A practical guide to fluid inclusion studies, New York: Glasgow Blackie, 239 . Sorby, H. C. (1858). On the microscopic structure of crystals, indicating the origin of minerals and rocks", The Quarterly Journal of the Geological Society of London, 14(1), 453-500. Teng, L. S. (1987). Stratigraphic records of the late Cenozoic Penglai Orogeny of Taiwan. Acta geologica taiwanica, 25, 205-224. Van der Pluijm, Ben A. and Marshak, S. (2004). Earth structure: An introduction to structural geology and tectonics. 2nd edition. New York: W. W. Norton and Company, Inc., 656.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101767	-
dc.description.abstract	本研究以廬山地熱區為研究區域，整合礦脈產狀與特徵，以及液包體分析，探討熱液流體的活動模式，並重建地熱區內流體的演化歷程。首先依照採集之礦脈產狀是否受到塑性變形，以及晶體型態是否有方向性排列，將礦脈分為三類，並根據其與區域構造的演化關係，反映出礦脈在造山帶中由深至淺的抬升歷程與岩體環境的轉變，因此將礦脈分為三個形成時期，並透過液包體顯微測溫實驗觀察構造演變下流體性質的改變。液包體顯微測溫結果顯示，三期礦脈之原生液包體最低均化溫度呈現下降趨勢，第一期約210°C、第二期約190°C至第三期約140-150°C，第三期礦脈次生液包體約130°C，代表流體溫度隨著地層抬升隨之降低。由冰融溫度檢測之流體鹽度顯示，各時期礦脈皆有可達10.0wt.% NaCl eq.左右的較高鹽度流體，可能指示不同時期的流體皆由同一深源供給，且推測因向斜區域構造的限制，使流體來自同一區域的向斜軸內；第三期出現<4.5wt.%的低鹽度流體，反映淺部天水的混合。各區域第三期礦脈液包體的溫度顯示馬海濮溪具有較高之溫度，可能與經過的斷層有關。綜合礦脈時序、液包體鹽度與流體溫壓條件，本研究提出廬山地熱區的熱液演化模式：早期深部由變質流體主導，鹽度可達10.0 wt.%，經液包體均化溫度壓力校正的形成溫度可達285°C，隨後岩體抬升與節理開展，熱液沿裂隙上升，後期因岩層接近地表，天水滲入並混合，形成低溫、低鹽的流體特徵，即鹽度<4.5 wt.%，流體溫度為150°C，甚至接近現今儲集層的溫度170°C。	zh_TW
dc.description.abstract	This study focuses on the Lushan geothermal area and integrates vein structures, field occurrence, and fluid inclusion analysis to investigate hydrothermal fluid behavior and reconstruct its evolutionary history. The collected veins are first classified into three types based on whether they experienced ductile deformation and whether their crystals display preferred orientations. Their geometric relationships with regional structures are then used to infer progressive exhumation from deep to shallow levels and changes in host-rock conditions, allowing definition of three vein-forming stages that frame the subsequent fluid inclusion microthermometry. Microthermometric data show a decreasing trend in minimum homogenization temperatures of primary inclusions from about 210 °C in Stage I, to 190 °C in Stage II, and 140–150 °C in Stage III, while secondary inclusions in Stage III yield around 130 °C, indicating cooling associated with uplift. Melting temperatures reveal consistently high values (5.0–10.0 wt.% NaCl eq.) across all stages, suggesting a deep, saline fluid source likely constrained within the synclinal axial zone. In contrast, low-salinity inclusions (<4.5 wt.% NaCl eq.) in Stage III reflect mixing with meteoric water. The Stage III vein fluid inclusion temperatures in different areas indicate that the Mahebu River site records higher temperatures, which are likely related to the faults passing through this area. Combining the timing of vein formation with fluid inclusion salinity and P–T conditions, this study proposes a hydrothermal evolution model for the Lushan geothermal system: early fluids were dominated by deep metamorphic fluids with salinities up to 10.0 wt.% and pressure-corrected trapping temperatures up to 285 °C, followed by upward migration along fractures during exhumation. In the late stage, near-surface conditions allowed infiltration and mixing of meteoric water, generating lower-temperature, lower-salinity fluids (salinity <4.5 wt.% NaCl eq., temperatures around 150 °C) that may comparable to present reservoir temperatures of approximately 170 °C.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2026-03-04T16:24:23Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2026-03-04T16:24:23Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	口試委員會審定書 i 致謝 ii 摘要 iii Abstract iv 目次 v 圖次 vii 表次 ix 第一章前言 1 1.1研究目的 1 1.2地質背景 1 1.3 前人研究 7 第二章研究方法 11 2.1野外工作 11 2.2室內研究 11 2.2.1礦脈成因分類 11 2.2.2顯微測溫實驗 12 2.2.3樣本製備流程 13 2.2.4顯微測溫實驗注意事項與液包體岩象觀察 14 2.2.5顯微測溫儀器溫度準確度校正 14 第三章礦脈之型態分析 16 3.1礦脈之形成機制 16 3.2礦脈之產狀分類 17 第四章液包體之顯微測溫分析 24 4.1液包體之概論及形成機制 24 4.2顯微測溫分析 26 4.2.1顯微測溫原理 26 4.2.2顯微測溫實驗步驟 27 4.2.3測溫結果之鹽度推論 28 4.3顯微測溫實驗結果 34 4.3.1液包體岩相觀察 34 4.3.2顯微測溫數據分析 43 4.3.3液包體形成溫度與壓力推論 46 第五章討論 59 5.1礦脈之形成先後順序 59 5.2液包體結果解釋與討論 60 5.2.1液包體均化溫度與流體溫度推估 60 5.2.2液包體鹽度分佈與流體來源初探 61 5.2.3液包體鹽度與均化溫度關聯性分析 63 5.2.4礦脈形成溫壓與構造演化 63 5.2.5流體來源推論 64 5.2.6區域液包體溫度與現今儲集層溫度比較 66 第六章結論 67 參考資料 70 附錄礦脈樣本液包體顯微測溫數據分析與計算結果 74	-
dc.language.iso	zh_TW	-
dc.subject	液包體	-
dc.subject	礦脈	-
dc.subject	顯微測溫	-
dc.subject	均化溫度	-
dc.subject	鹽度	-
dc.subject	Fluid inclusion	-
dc.subject	Vein	-
dc.subject	Microthermometry	-
dc.subject	Homogenization temperature	-
dc.subject	Salinity	-
dc.title	從礦脈中液包體重建臺灣廬山地熱區之熱液歷史	zh_TW
dc.title	Studies of Fluid Inclusions for Reconstructing Hydrothermal History of the Taiwan Lushan Geothermal Area	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	羅偉;陳惠芬;盧乙嘉	zh_TW
dc.contributor.oralexamcommittee	Wei Lo;Huei-Fen Chen;Yi-Chia Lu	en
dc.subject.keyword	液包體,礦脈顯微測溫均化溫度鹽度	zh_TW
dc.subject.keyword	Fluid inclusion,VeinMicrothermometryHomogenization temperatureSalinity	en
dc.relation.page	89	-
dc.identifier.doi	10.6342/NTU202600738	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2026-02-23	-
dc.contributor.author-college	理學院	-
dc.contributor.author-dept	地質科學系	-
dc.date.embargo-lift	2026-03-05	-
顯示於系所單位：	地質科學系

文件中的檔案：

檔案	大小	格式
ntu-114-1.pdf	4.68 MB	Adobe PDF	檢視/開啟

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。