浙江小將-梁弄岩體及其包體之礦物化學與地球化學研究

Chiung-Mei Yen; 顏琼美

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/39059

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳正宏(Cheng-Hong Chen)
dc.contributor.author	Chiung-Mei Yen	en
dc.contributor.author	顏琼美	zh_TW
dc.date.accessioned	2021-06-13T16:59:48Z	-
dc.date.available	2006-02-16
dc.date.copyright	2005-02-16
dc.date.issued	2005
dc.date.submitted	2005-02-03
dc.identifier.citation	中文部分 Martin, H.、Bonin, B.、Didier, J.、江博明、Lameyre, J.、裘愉卓、王一先，1991，中國東南部福州花崗質雜岩的岩石學和地球化學。地球化學，第2期，101-111頁。王一先、趙振華、包志偉、李獻華，1997，浙江花崗岩類地球化學與地殼演化──Ⅰ.顯生宙花崗岩類。地球化學，第26卷，第5期，1-15頁。王蓉嶸、劉家遠，1993，福建魁岐晶洞鹼性花崗岩特徵及成因。桂林冶金地質學院學報，第13卷，第1期，14-23頁。田蓉禮，1996，中國東南沿海福建燕山晚期花崗複式岩體核飛跡定年與氬氬定年結果之比較研究。國立台灣大學地質學研究所博士論文，共323頁。李寄嵎，1994，澎湖地區玄武岩類與福建地區基性脈岩之定年學與地球化學研究兼論中生代晚期以來中國東南地函之演化。國立台灣大學地質學研究所博士論文，共226頁。李寄嵎、蔡榮浩、何孝恆、楊燦堯、鍾孫霖、陳正宏，1997，應用X光螢光分析儀從事岩石樣品之定量分析(I)主要元素。中國地質學會86年年會論文摘要集，418-420頁。杜楊松、王德滋、陳克榮，1990，浙東南沿海地區中生代火山-侵入雜岩的特徵、成因及分佈規律。地質學報，第三期，215-225頁。李繼亮，1992，中國東南海陸岩石圈結構與演化研究。北京中國科學技術出版社。沈渭洲、凌洪飛、李武顯、黃小龍、王德滋，1999，中國東南部花崗岩類Nd-Sr同位素研究。高校地質學報，第5卷，第1期，22-32頁。呂學諭，2001，中國東南燕山期岩漿活動之地質動力學分析。國立台灣大學地質學研究所博士論文，共209頁。邢光福、楊祝良、毛建仁、舒良樹、沈加林、孫強輝、陳榮、陶奎元，2002，東南大陸邊緣早侏儸世火成岩特徵及其構造意義。地質通報，第21卷，第7期，384-391頁。林蔚，1994，金門地區燕山晚期花崗岩類之地球化學及熱歷史研究。國立台灣大學地質學研究所碩士論文，共92頁。林蔚，2001，華南沿海地區晚燕山期侵入岩漿活動及大地構造意義。國立台灣大學地質學研究所博士論文，共237頁。周珣若、吳克隆，1994，漳州I-A型花崗岩。北京科學出版社。邱檢生、王德滋、McInnes, B. I. A.，1999，浙閩沿海地區I型-A型複合花崗岩體的地球化學及成因。岩石學報，第15卷，第2期，237-246頁。徐夕生、周新民、王德滋，1999，殼幔作用與花崗岩成因──以中國東南沿海為例。高校地質學報，第5卷，第3期，241-250頁。浙江省區域地質誌，1989，地質礦產部地質專報（一），第11號，地質出版社。浙江岩石地層，1997，浙江省地質礦產局編浙江省岩石地層。中國地質大學出版社。陳三元、毛建仁、薛懷民，1991，浙東燕山晚期花崗岩的地球化學特徵。火山地質與礦產，第12卷，第4期，60-71頁。陳正宏，1990，台灣之火成岩。經濟部中央地質調查所出版。陳江峰、周泰禧、印春生、Foland, K. A.，1991，浙東南某些中生代侵入岩體的40Ar-39Ar年齡測定。岩石學報，第7卷，第3期，37-44頁。陳江峰、周泰禧、李學明、Foland, K. A.、朱泉炳、毛存孝、朱乃娟，1992，中國東南地區中生代岩漿岩的Sr、Nd同位素組成及其大地構造意義。，119-130頁。陳江峰、Foland, K. A.、劉義茂，1993，蘇州複式花崗岩體的精確40Ar-39Ar定年。岩石學報，第9卷，第1期，77-85頁。張德全、孫桂英，1988，中國東部花崗岩。中國地質大學出版社。彭亞鳴、董傳萬，1991，浙江青田鹼性花崗岩研究。南京大學學報(地球科學)，第3卷，第2期，138-147頁。葉德隆、鄔金華、陳能松，1995，岩石典型結構分析。中國地質大學出版社。董傳萬、彭亞鳴，1992，浙江青田I型和A型花崗岩的造岩礦物特徵及成岩的物理化學條件。南京大學學報(地球科學)，第4卷，第4期，33-42頁。黃萱、孫世華、DePaolo, D. J.、吳克隆，1986，福建省白堊紀岩漿岩Nd、Sr同位素研究。岩石學報，第2卷，第2期，50-63頁。楊小青，1998，中國東南平潭-東山變質帶之氬同位素熱定年學研究。國立台灣大學地質學研究所博士論文，共217頁。福建省區域地質誌，1985，地質礦產部地質專報（一），第4號，地質出版社。賴宜欣，1995，福建白堊紀花崗岩之地球化學及礦物化學研究。國立台灣大學地質科學系研究所碩士論文，共94頁。英文部分 Abdel-Rahman, A. M., 1994. Nature of biotites from alkaline, calc-alkaline, and peraluminous magmas. Journal of Petrology 35, 525-541. Anderson, A. T., 1968. Oxidation of the Lablache lake titaniferous magnetite deposit, Quebec. Journal of Geology 76, 528-547. Barbarin, B., 1990. Granitoids: main petrogenetic classifications in relation to origin and tectonic setting. Geological Journal 25, 227-238. Barbarin, B., 1999. A review of the relationships between granitoid types, their origins and their geodynamic environments. Lithos 46, 605-626. Barnes, C. G., Petersen, S. W., Kistler, R. W., Murray, R., Kays, M. A., 1996. Source and tectonic implications of tonalite-trondhjemite magmatism in the Klamath Mountains. Contributions to Mineralogy and Petrology 123, 40-60. Bonin, B., Azzouni-Sekkal, A., Bussy, F., Ferrag, S., 1998. Alkali-calcic and alkaline post-orogenic granite magmatism: petrologic constraints and geodynamic setting. Lithos 45, 45-70. Buddington, A. F., Lindsley, D. H., 1964. Iron-titanium oxide minerals and synthetic equivalents. Journal of Petrology 5, 310-357. Chappell, B. W., 1997. Compositional variation within granite suites of the Lachlan Fold Belt: its causes and implication for the physical state of granite magma. Transactions of the Royal Society of Edinburgh: Earth Sciences 88, 159-170. Chappell, B. W., White, A. J. R., 1974. Two contrasting granite types. Pacific Geology 8, 173-174. Chappell, B. W., White, A. J. R., Wyborn, D., 1987. The important of residual source material (restite) in granite petrogenesis. Journal of Petrology 28, 1111-1138. Chappell, B. W., White A. J. R., 2001. Two contrasting granite types: 25 years later. Australian Journal of Earth Sciences 48, 489-499. Charoy, B., Raimbault, L., 1994. Zr-, Th-, and REE-rich biotite differentiates in the A-type granite pluton of Suzhou (Eastern China): the key role of fluorine. Journal of Petrology 35(4), 919-962. Charvet, J., Lapierre, H., Yu, Y. W., 1994. Geodynamic significance of the Mesozoic volcanism of southeastern China. Journal of Southeast Asian Earth Sciences 9(4), 387-396. Chen, C. H., Jahn, B. M., Lee, T., Chen, C. H., Cornichet, J., 1990. Sm-Nd isotopic geochemistry of sediments from Taiwan and implications for the tectonic evolution of southeast China. Chemical Geology 88, 317-332. Chen, C. H., Lin, W., Lee, C. Y., Tien, J. L., Lu, H. Y., Lai, Y. H., 2000. Cretaceous fractionated I-type granitoids and metaluminous A-type granites in SE China: the Late Yanshanian post-orogenic magmatism. Transaction of Royal Society of Edinburgh: Earth Sciences 91, 1-11. Chen, C. H., Tung, T. C., 1984. On-line data reduction for electron microprobe analysis. Acta Geologica Taiwanica 22, 196-200. Chen, J. F., Jahn, B. M., 1998. Crustal evolution of southeastern China: Nd and Sr isotopic evidence. Tectonophysics 284, 101-133. Chung, S. L., Cheng, H., Jahn, B. M., O’Reilly, S. Y., Zhu, B. Q., 1997a. Major and trace element, and Sr-Nd isotope constraints on the origin of Paleogene volcanism in South China prior to the South China Sea opening. Lithos 40, 203-220. Clarke, D. B., 1992. Granitoid rocks. Chapman & Hall, 283pp. Collins, W. J.,1996. Lachlan Fold Belt granitoids: products of three-component mixing. Transaction of Royal Society of Edinburgh: Earth Sciences 87, 171-281. Collins, W. J., Beams, S. D., White, A. J. R., Chappell, B. W., 1982. Nature and origin of A-type granites with particular reference to southeastern Australia. Contributions to Mineralogy and Petrology 80, 189-200. Deer, W. A., Howie, R. A., Zussman, J., 1992. An Introduction to the Rock-Forming Minerals. 2nd ed. Longman Scientific & Technical, 696pp. Didier, J., Barbarin, B., 1991. Enclaves and Granite Petrology. Amsterdam: Elsevier Science Publishers, New York, 615pp. Droop, G. T. R., 1987. A general equation for estimating Fe3+ concentrations in the ferromagnesian silicates and oxides from microprobe analysises, using stoichiometric criteria. Mineralogical Magazine 51, 431-435. Drummond, M. S., Defant, M. J., 1990. A model for trondhjemite-tonalite-dacite genesis and crustal growth via slab melting: Archean to modern comparisons. Journal of Geophysical Research 95, 21503-21521. Eby, G. N., 1990. The A-type granitoids: a review of their occurrence and chemical characteristics and speculations on their petrogenesis. Lithos 26, 115-134. Eby, G. N., 1992. Chemical subdivision of the A-type granitoids: petrogenetic and teconic implications. Geology 20, 641-644. Fenn P. M., 1986. On the origin of graphic granite. American Mineralogist 71, 325-330. Gilder, S. A., Gill, J., Coe, R. S., Zhao, X. X., Liu, Z. W., Wang, G., Yuan, K., Liu, W. L., Kuang, G. D., Wu, H. R., 1996. Isotopic and paleomagnetic constraints on the Mesozoic tectonic evolution of south China. Journal of Geophysical Research 101(B7), 16137-16154. Hammarstrom, J. M., Zen, E-an., 1986. Aluminium in hornblende: an empirical igneous geobarometer. American Mineralogist 71, 1297-1313. Hong, D. W., Wang, S. G., Han, B. F., Jin, M. Y., 1996. Post-orogenic alkaline granites from China and comparisons with anorogenic alkaline granites elsewhere. Journal of Southeast Asian Earth Sciences 13(1), 13-27. Hsu, K. J., Li, J., Chen, H., Wang, Q., Sun, S., Sengor, A. M. C., 1990. Tectonics of South China: Key to understanding West Pacific geology. Tectonophysics 183, 9-39. Hyndman D. W., 1985. Petrology of igneous and metamorphic rocks. 2nd ed. McGraw-Hill, 786pp. Jahn, B. M., 1974. Mesozoic thermal events in southeast China. Nature 248, 480-483. Jahn, B. M., Chen, P. Y., Yen, T. P., 1976. Rb-Sr ages of granitic rocks in southeastern China and their tectonic significance. Geological Society of America Bulletin 86, 763-776. Jahn, B. M., Zhou, X. H., Li, J. L., 1990. Formation and tectonic evolution of Southeastern China and Taiwan: Isotopic and geochemical constraints. Tectonophysics 183, 145-160. Kadioğlu Y. K., Güleç, N., 1999. Types and genesis of the enclaves in Central Anatolian granitoids. Geological Journal 34, 243-256. Lan, C. Y., Jahn, B. M., Mertzman, S. A., Wu, T. W., 1996. Subduction-related granitic rocks of Taiwan. Journal of Southeast Asian Earth Science 14, 11-28. Lan, C. Y., Chung, S. L., Mertzman, S. A., Chen, C. H., 1995a. Mafic dikes from Chinmen and Liehyu islands, off southeast China: petrochemical characteristics and tectonic implications. Journal of the Geological Society of China 38(3), 183-213. Lan, C. Y., Lee, T., Jahn, B. M., Yui, T. F., 1995b. Taiwan as a witness of repeated mantle inputs—Sr-Nd-O isotopic geochemistry of Taiwan granitoids and metapelites. Chemical Geology 124, 287-303. Lan, C. Y., Chung, S. L., Mertzman, S. A., Chen, C. H., 1997. Mineralogy and geochemistry of granitic rocks from Chinmen, Liehyu and Dadan islands, Fujian. Journal of the Geological Society of China 40(3), 527-558. Lapierre, H., Jahn, B. M., Charvet, J., Yu, Y. W., 1997. Mesozoic magmatism in Zhejiang province and its relation with the tectonic activities in SE China. Tectonophysics 274, 321-338. Leake, B. E., 1978. Nomenclature of amphiboles. American Mineralogist 63(11-12), 1023-1052. Lee, C. Y., Chung, S. L., Chen, C. H., Hsieh, Y. L., 1993. Mafic granulite xenoliths from Penghu Islands: evidence for basic lower crust in SE China continental margin. Journal of Geological Society of China 36(4), 351-379. Li, X. H., 2000. Cretaceous magmatism and lithospheric extension in Southeast China. Journal of Asian Earth Sciences 18, 293-305. Li, Z. X., 1998. Tectonic history of the major East Asian lithospheric blocks since the Mid-Proterozoic—a synthesis. Mantle Dynamics and Plate Interactions in East Asia Geodynamics 27, 221-243. Lu, H. Y., Tien, J. L., Lo, C. H., Chen, C. H., 1999. Thermal modeling and chronological constraints of granitic plutonism in Zhangzhou Igneous Complex, SE China. Journal of the Geological Society of China 42, 521-541. Martin, H., 1999. Adakitic magmas: modern analogues of Archaean granitoids. Lithos 46, 411-429. Martin, H., Bonin, B., Capdevila, R., Jahn, B. M., Lameyre, J., Wang, Y., 1994. The Kuiqi peralkaline granitic complex (SE China): Petrology and geochemistry. Journal of Petrology 35(4), 983-1015. Mysen, B. O., 1979. Trace element partitioning between garnet peridotite minerals and water-rich vapor: experimental data from 5 to 30 kbar. American Mineralogist 64, 274-287. Patino, Douce, A. E., 1997. Generation of metaluminous A-type granites by low-pressure melting of calc-alkaline granitoids. Geology 25(8), 743-746. Pearce, J. A., Harris, N. B. W., Tindel, A. G., 1984. Trace element discrimination diagrams for the tectonic interpretation of granitic rocks. Journal of Petrology 25, 956-983. Pearce, J. A., Peate, D. W., 1995. Tectonic implicaations of the composition of volcanic arc magmas. Annual Review of Earth Planetary Scicences 23, 251-285. Pitcher, W. S., 1997. The nature and origin of granite. 2nd ed. Chapman & Hall. Powell, R., Powell, M., 1977. Geothermometry and oxygen barometry using coexisting iron-titanium oxides: a reappraisal. Mineralogical Magazine 41, 257-263. Robert, M. P., Clemens, J. D., 1993. Origin of high-potassium, calc-alcaline, I-type granitoids. Geology 21, 825-828. Schmidt, M. W., 1992. Amphibole composition in tonalite as a function of pressure: an experimental calibration of the Al-in-hornblende barometer. Contribution to Mineralogy and Petrology 110, 304-310. Stephens, W. E., 2001. Polycrystalline amphibole aggregates (clots) in granites as potential I-type restite: an ion microprobe study of rare-earth distributions. Australian Journal of Earth Sciences 48, 591-601. Streckeisen, A., 1976. To each plutonic rock its proper name. Earth Science Review, 12, 1-33. Sylvester, P. J., 1989. Post-collisional alkaline granites. Journal of Geology 97, 261-280. Tatsumi, Y., Eggins, S., 1995. Subduction zone magmatism. Blackwell Scientific Publication, Cambridge, 211pp. Taylor, R. P., Strong, D. F., Fryer, B. J., 1981. Volatile control of contrasting trace element distributions in peralkaline granitic and volcanic rocks. Contribution to Mineralogy and Petrology 77, 267-271. Thompson, A. B., 1999. Some time-space relationships for crustal melting and granitic intrusion at various depths. In: Castro, A., Fernandez, C.,Vigneresse, J. L., (eds), Understanding granites: Integrating new and classic techniques. Geological Society, London, Speical publication 168, 7-25. Tien, J. L., Chen, C. H., Lo, C. H., Lai, Y. S., 1997. Contrasting cooling rates of coeval granitic plutons in the Zhangzhou Igneous Complex, SE China: Evidences from 40Ar/39Ar thermochronology and Al-amphibole geobarometer. Journal Geological Society of China 40(3), 607-624. Tong, W. X., Tobisch, O. T., 1996. Deformation of granitoid plutons in the Dongshan area, southeast China: constraints on the physical conditions and timing of movement along the Changle-Nanao shear zone. Tectonophysics 267, 303-316. Turner, S., Sandiford, M., Foden, J., 1992. Some geodynamic and compositional constraints on 'postorogenic' magmatism. Geology 20, 931-934. Vernon, R. H., 1983. Restite, xenoliths and microgranitoid enclaves in granites. Journal and Proceedings of the Royal Society of New South Wales 116, 77-103. Vigneresse, J. L., 1995a. Control of granite emplacement by regional deformation. Tectonophysics 249, 173-186. Vigneresse, J. L., 1995b. Crustal regime of deformation and ascent of granitic magma. Tectonophysics 249, 187-202. Whalen, J. B., Currie, K. L., Chappell, B. W., 1987. A-type granites: geochemical characteristics, discrimination, and petrogenesis. Contribution to Mineralogy and Petrology 95, 407-419. White, A. J. R., 2001. Water, restite and granite mineralisation. Australian Journal of Earth Sciences 48, 551-555. White, A. J. R., Chappell, B. W., Wyborn, D., 1999. Application of the restite model to the Deddick Granodiorite and its enclaves: a reinterpretation of the observations and data of Maas et al. (1997). Journal of Petrology 40(3), 413-421. Wilson, M., 1989. Igneous Petrogenesis: A Global Tectonic Approach. Chapman & Hall, London, 466pp. Xu, X., Dong, C., Li, W., Zhou, X., 1999. Late Mesozoic intrusive complexes in the coastal area of Fujian, SE China: the significance of the gabbro-diorite-granite association. Lithos 46, 299-315. Zhou, X. M., Li, W. X., 2000. Origin of Late Mesozoic igneous rocks in Southeastern China: implications for lithosphere subduction and underplating of mafic magmas. Tectonophysics 326, 269-287.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/39059	-
dc.description.abstract	華南地區晚燕山期侵入岩漿活動，廣布晚侏儸紀至早白堊紀的花崗岩類，主要發育於浙、閩沿海地區，即東南沿海岩漿活動帶上，包括大量I型花崗岩類、及少量的A型花崗岩的出露並伴隨雙模式火山活動的產物，本文除了以浙江小將、梁弄兩岩體之主岩及其包體為主要分析目標外，相關討論另包括浙江地區龍王堂、山頭鄭、桃花島、青田及福建地區福州、漳州、魁岐、筆架山等岩體標本，皆屬於華南晚燕山期花崗岩類的範疇。本研究小將岩體之包體標本共包括三類包體，由礦物化學與地球化學分析結果顯示，小將岩體的第一類包體與主岩相似，兩者間具有結晶分化的關係，包體部分可能來自早期冷凝的基性組分(基性冷凝邊)，形成同源包體，而第三類包體具有富鎂、貧鈣的特徵，則為第一類組合早期結晶出來的基性產物。第二類包體屬於中鉀系列，相對於其他包體而言，具有低鉀、高鈉、高鋁的特徵，其Sr同位素及地化特徵，顯示為後造山型岩漿活動特徵，其來源可能為後造山一開始底侵的基性岩漿早期侵入所成的岩類，後被高結晶分化的主岩所帶至淺處。本研究梁弄岩體標本只含一類包體，顆粒大小與主岩一致，所有的標本分析呈現一致或漸變的現象，並顯示高溫至低溫的結晶溫度，其間具有結晶分化的關係，包體屬於分化的產物。由礦物化學分析結果顯示，礦物的結晶狀態處於低溫低壓，並由高水壓轉變至低水壓的環境；另利用角閃石地質壓力計，求得岩漿侵入時的深度約為3-8公里，與福建福州、漳州複式岩體研究結果相符，皆說明本研究標本屬於淺侵入的生成環境。小將-梁弄岩體的分析結果與浙閩地區晚燕山期部分花崗岩類的比較結果，其侵位年代、侵位空間分佈、地化特徵皆十分相近，同屬於晚燕山期後造山型的I-A型花崗岩，顯示為擠壓到張裂的生成環境。	zh_TW
dc.description.abstract	Late Yanshanian magmatism in South China caused vast granitic intrusions including large amounts of I-type granitoids and small amounts of A-type granites from late Jurassic to early Cretaceous, distributed mainly in the Southeast Coast Magmatic Belt (SCMB). The Xiaojiang-Liangnong Complexes and their enclaves in Zhejiang is the target of this study, samples from Longwangtang, Taohua Island, Qingtian in Zhejiang and Fuzhou, Zhangzhou, Kuiqi, Bijiashan in Fujian are concerned. Xiaojiang Complexes include three types of enclaves and two types of hosts. The analyses of mineral chemistry and geochemistry indicate that characters of the first type of enclaves are similar to their hosts, which could have resulted from differentiation of the enclaves representing fragments of early, chilled margins, disrupted during the ascent of magmas. The third type of enclaves are characterized by high-Mg, low-Ca compositions, and they represent the basic products of early differentiation from magmas of the first type. The second type of enclaves belonging to medium-K series are characterized by high-Al,Na compositions. The Sr isotope and geochemical data indicate they could differentiate from the underplating basic magmas of post-orogenic stage of Late Yanshanian magmatism. Liangnong Complexes include one type of enclaves and two types of hosts. All samples from Liangnong Complexes belong to products of differentiation. Using the Al-in-amphibole geobarometer, the samples of this study were estimated to have been emplaced at shallow depths (3-8 km). The analyses results of Xiaojiang-Liangnong Complexes are close to the emplacement ages, depths, geochemical characters of the Late Yanshanian granitoids in Zhejiang and Fujian in this study. They all belong to the intrusions of I- and A-type granitoids of post-orogenic stage of Late Yanshanian magmatism reflecting tectonism from compressional to extensional environment.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T16:59:48Z (GMT). No. of bitstreams: 1 ntu-94-R90224213-1.pdf: 3411744 bytes, checksum: 6c08d7b15de9621105bbd2f165c40559 (MD5) Previous issue date: 2005	en
dc.description.tableofcontents	目錄第一章緒論 1 1-1 前言 1 1-2 地質背景 1 1-3 前人研究 6 1-4 研究動機與目的 6 第二章研究方法 8 2-1 岩象學觀察 8 2-2 礦物化學分析 8 2-3 全岩地球化學分析 10 2-3.1 主要元素 10 2-3.2 微量元素 10 2-3.3 鍶同位素 10 第三章分析結果與應用 11 3-1 岩象學觀察 11 3-1.1 小將岩體 12 3-1.1.1 第一類組合 12 3-1.1.2 第二類組合 14 3-1.2 梁弄岩體 15 3-1.2.1 第一類組合 15 3-1.2.2 第二類組合 15 3-1.3 龍王堂、山頭鄭岩體 16 3-1.4 point counter計算 19 3-2 礦物化學分析 22 3-2.1 長石 22 3-2.2 黑雲母 26 3-2.3 角閃石 32 3-2.4 輝石 41 3-2.5 鈦鐵氧化物 42 3-3 地球化學分析 44 3-3.1 主要元素分析結果 44 3-3.2 微量元素分析結果 58 3-3.2.1 稀土元素地球化學 58 3-3.2.2 微量元素地球化學 63 3-3.3 同位素分析結果 73 第四章綜合討論 76 4-1 小將、梁弄岩體及其包體研究 76 4-1.1 從岩象學與礦物化學探討包體之成因 76 4-1.2 小將、梁弄岩體及其包體之地化特徵與成因模式 80 4-1.3 梁弄岩體之A型花崗岩 83 4-2 小將、梁弄岩體與浙閩地區晚燕山期花崗岩的關係 85 4-2.1 岩體侵入時代 86 4-2.2 地體構造特徵 87 第五章結論 88 誌謝 90 參考文獻 91 中文部分 91 英文部分 93 附錄 99 圖版 99 附表 109 表目表1-1 浙江鈣鹼系列侵入岩類野外採集標本 4 表2-1 分析礦物化學各元素之標準礦物 9 表3-1 岩體標本編號 11 表3-2 兩類組合之標本編號表 12 表3-3 小將與梁弄岩體之岩象學特徵 17 表3-4 礦物組成百分比 20 表3-5 角閃石之化學成分及地質壓力計算結果 36 表3-6 小將、梁弄岩體之主要元素及微量元素分析結果 45 表3-7 龍王堂、山頭鄭岩體之主要元素及微量元素分析結果 51 表3-8 同位素分析結果 75 表4-1 包體之成因模式及特徵 76 表4-2 浙閩地區定年資料 86 表4-3 晚燕山晚期之岩漿活動分期 87 圖目圖1-1 浙閩地區晚燕山花崗岩分佈圖 3 圖1-2 小將-梁弄岩體分析標本採樣點圖 5 圖3-1 深成岩之QAP分類圖 21 圖3-2 長石之An-Ab-Or圖 23 圖3-3 黑雲母之鐵質-四配位鋁-氧化鈦成分圖 27 圖3-4 黑雲母之四配位鋁-氧化鈦成分圖 29 圖3-5 黑雲母之MgO-Al2O3變化圖 31 圖3-6 角閃石分類圖 33 圖3-7 角閃石之四配位鋁-氧化鈦-(Na+K)成分圖 34 圖3-8 角閃石之鋁含量與壓力應用圖 40 圖3-9 小將岩體所含輝石之Wo-En-Fs圖 42 圖3-10 鈦鐵氧化物之端成分命名圖 43 圖3-11 深成岩之TAS分類圖 52 圖3-12 SiO2-K2O分類圖 53 圖3-13 Na2O-K2O圖 54 圖3-14 K2O-Na2O-CaO三角圖 54 圖3-15 哈克圖 56 圖3-16 鋁飽和指數對A/NK作圖 57 圖3-17 稀土元素分佈圖 59 圖3-18 梁弄A與浙閩地區A型花崗岩之稀土元素分佈圖 63 圖3-19 以SiO2對總稀土含量作圖 64 圖3-20 以La、Yb對總稀土含量(total REE)作圖 65 圖3-21 以SiO2對大離子半徑元素及相容性元素作圖 67 圖3-22 多元素分佈圖 68 圖3-23 I-A型花崗岩及高結晶分化I型花崗岩之判別圖 70 圖3-24 地體構造判別圖 71 圖3-25 鍶同位素Isr對SiO2作圖 74 圖3-26 以Y對Sr/Y作圖 82 圖3-27 以(Yb)N對(La/Yb)N作圖 82 附錄圖版一小將第一類主岩(方口) 99 圖版二小將第一類包體(方口) 99 圖版三小將第一類主岩(上朱部) 100 圖版四小將第一類包體(上朱部) 100 圖版五小將第一類包體(上朱部) 101 圖版六小將第三類包體 101 圖版七小將第三類包體 102 圖版八小將第三類包體 102 圖版九小將第二類主岩 103 圖版十小將第二類主岩(山門) 103 圖版十一小將第二類包體 104 圖版十二小將第二類包體 104 圖版十三梁弄第一類主岩 105 圖版十四梁弄第一類主岩 105 圖版十五梁弄第一類包體 106 圖版十六梁弄第一類包體 106 圖版十七梁弄第二類主岩 107 圖版十八梁弄A(晶洞鹼長花崗岩) 107 圖版十九梁弄A(晶洞中的榍石) 108 圖版二十梁弄A(晶洞中的綠簾石) 108 附表一長石類之礦物化學分析結果 109 附表二黑雲母之礦物化學分析結果 117 附表三角閃石之礦物化學分析結果 127 附表四輝石之礦物化學分析結果 133 附表五鈦鐵氧化物之礦物化學分析結果 135
dc.language.iso	zh-TW
dc.subject	後造山岩漿活動	zh_TW
dc.subject	晚燕山期花崗岩	zh_TW
dc.subject	包體	zh_TW
dc.subject	Enclaves	en
dc.subject	post-orogenic magmatism	en
dc.subject	Late Yanshanian granitoids	en
dc.title	浙江小將-梁弄岩體及其包體之礦物化學與地球化學研究	zh_TW
dc.title	Mineral Chemistry and Geochemistry of the Xiaojiang-Liangnong Complexes and their Enclaves in Zhejiang	en
dc.type	Thesis
dc.date.schoolyear	93-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	藍晶瑩,楊燦堯
dc.subject.keyword	晚燕山期花崗岩,包體,後造山岩漿活動,	zh_TW
dc.subject.keyword	Enclaves,Late Yanshanian granitoids,post-orogenic magmatism,	en
dc.relation.page	138
dc.rights.note	有償授權
dc.date.accepted	2005-02-03
dc.contributor.author-college	理學院	zh_TW
dc.contributor.author-dept	地質科學研究所	zh_TW
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-94-1.pdf 未授權公開取用	3.33 MB	Adobe PDF

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。