[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5467/JKESS.2012.33.5.434

Temperature and Timing of the Mylonitization of the Leucocratic Granite in the Northeastern Flank of the Taebaeksan Basin

Kim, Hyeong-Soo (Department of Earth Science Education, Kyungpook National University)

Publication Information

Journal of the Korean earth science society / v.33, no.5, 2012 , pp. 434-449 More about this Journal

Abstract

The Mesozoic leucocratic granite in the northeastern margin of the Taebaeksan Basin was transformed to protomylonite and mylonite. Mylonitic foliations generally strike to NWWNW and dip to NE with the development of a sinistral strike-slip (top-to-the-northwest) shear sense. Grain-size reduction of feldspar in the mylonitized leucocratic granite occurred due to fracturing, myrmekite formation and neocrystallization of albitic plagioclase along the shear fractures of K-feldspar porphyroclasts. As the deformation proceeded, compositional layering consisting of feldspar-, quartz- and/or muscovite-rich layers developed in the mylonite. In the feldspar-rich layer, fine-grained albitic plagioclase and interstitial K-feldspar were deformed dominantly by granular flow. On the other hand, quartz-rich layers containing core-mantle and quartz ribbons structures were deformed by dislocation creep. Based on calculations from conventional two-feldspar and ternary feldspar geothermometers, mylonitization temperatures of the leucocratic granite range from 360 to $450^{\circ}C$ . It thus indicates that the mylonitization has occurred under greenschist-facies conditions. Based on the geochemical features and previous chronological data, the leucocratic granite was emplaced during the Middle Jurassic at volcanic arc setting associated with crustal thickening. And then the mylonitization of the granite occurred during the late Middle to Late Jurassic (150-165 Ma). Therefore, the mylonitization of the Jurassic granitoids in the Taebaeksan Basin was closely related to the development of the Honam shear zone.

Keywords

The Mesozoic leucocratic granite; Taebaeksan Basin; mylonitization temperatures;

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Times Cited By KSCI : 3 (Citation Analysis)

Reference
Cited By KSCI

1	Sun, S.S. and McDonough, W.F., 1989, Chemical and isotopic systematic of oceanic basalts: implications for mantle composition and process. In Saunder, A.D., Norry, M.J. (eds.), Magmatism in the Ocean Basins. Geological Society of London Special Publications, 313-345.
2	Turek, A. and Kim, C-B., 1995, U-Pb zircon ages of Mesozoic plutons in the Danyang-Geochang area, Ryeongnam massif, Korea. Geochemical Journal, 29, 243-258. DOI
3	Watson, E.B. and Harrison, T.M., 1983, Zircon saturation revisited: Temperature and composition effects in a variety of crustal magma type. Earth and Planetary Science Letters, 64, 295-304. DOI ScienceOn
4	William, I.S., Cho, D-L., and Kim, S.W., 2009, Geochronology and geochemical and Nd-Sr isotopic characteristics of Triassic plutonic rocks in the Gyeonggi Massif, South Korea: Constraints on Triassic post-collisional magmatism. Lithos, 107, 239-256. DOI ScienceOn
5	Yanai, S., Park, B.-S., Otoh, S., 1985, The Honam shear zone (South Korea): Deformation and tectonic implication in the Far east. Scientific Papers of the College of Arts and Sciences, University of Tokyo, 35, 181-210.
6	Yin, A. and Nie, S., 1993, An indentation model for the north and south China collision and the development of the Tan-lu and Honam fault systems, eastern Asia. Tectonics, 12, 801-813. DOI ScienceOn
7	Perchuk, L.L., 1989, P-T-fluid regimes of metamorphism and related magmatism with specific reference to the granulite-facies Sharyzhalgay complex of Lake Baikal. In Daly, J.S., Cliff, R.A., and Yardley, B.W.D. (eds.), Evolution of Metamorphic Belts, Geological Society of London Special Publication, London, UK, 275-291.
8	Powell, R. and Powell, M., 1977, Plagioclase-alkali feldspar geothermometry revisited. Mineralogical Magazine, 41, 253-256. DOI
9	Ree, J.-H., Kwon, S.-H., and Park, Y., 2001. Pretectonic and posttectonic emplacements of the granitoids in the south central Okchon belt, South Korea: Implications for the timing of strike-slip shearing and thrusting. Tectonics, 20, 850-867. DOI ScienceOn
10	Ree, J.-H., Kim, H.S., Han, R., and Jung, H., 2005, Grainsized reduction of feldspars by fracturing and neocrystallization in a low-grade granitic mylonite and its rheological effect. Tectonophysics, 407, 227-237. DOI
11	Sagong, H., Kwon, S.-T., and Ree, J.-H., 2005. Mesozoic episodic magmatism in South Korea and its tectonic implication. Tectonics, 24, 1-18.
12	Stipp, M., Stuntiz, H., Heilbronner, R., and Schimid, S.M., 2002, The eastern Tonale fault zone: a 'natural laboratory' for crystal plastic deformation of quarts over a temperature range from 250 to 700 $^{\circ}C$ . Journal of Structural Geology, 24, 1861-1884. DOI
13	Stormer, J.C. and Whitney, J.A., 1985, Two-feldspar and iron-titanium oxide equilibria in silicic magmas and the depth of origin of large volume ash-flow tuffs. Amerian Mineralogist, 70, 52-64.
14	Stünitz, H. and Fitz Gerald, J.D., 1993, Deformation of granitoids at low metamorphic grade: II granular flow in albite-rich mylonite. Tectonophysics, 221, 299-324. DOI
15	Miller, C.F., McDowell, S.M., and Mapes, R.W., 2003, Hot and cold granite? Implications of zircon saturation temperatures and preservation of inheritance. Geology, 31, 529-532. DOI ScienceOn
16	Lee, J.I., Jwa, Y.-J., Park, C.-H., Lee, M.J., Moutte, J., and Kagami, H., 1999, Sr and Nd isotopic compositions of late Paleozoic Youngju and Andong granites in the northeastern Yeongnam Massif, Korea. Geocheimcal Journal, 33, 153-165. DOI
17	Lee, S.-R., Lee, B.-J., Cho, D.-L., Kee, W.-S., Kim, B.-C., Song, K.-Y., Hwang, J.H., and Choi, B-Y., 2003, SHRIMP U-Pb zircon ages of granites in Jeonju shear zone: Review on movement timing of the Honam shear zone. The annual Joint meeting of the Petrological and Mineralogical Society of Korea.
18	Middlemost, E.A.K., 1985, Magma and Magmatic rocks: An Introduction to Igneous Petrology. Longman. Inc., London, UK, 266 p.
19	Min, K.W. and Kim, S.B., 1990, Petrogeochemistry of the granitic rocks distributed in Imgye and Samhwa area, Kangweon-Do. Research Report the Institute of Industrial Technology, 10, 33-48.
20	Nakamura, N., 1974, Determination of REE, Ba, Fe, Mg, Na, and K in carbonaceous and ordinary chondrites. Geochimica et Cosmochimica Acta, 38, 757-775. DOI ScienceOn
21	Park, K.-H., Kim, M.J., Yang, Y.S., and Cho, K.O., 2010, Age Distribution of the Jurassic Plutons in Korean Peninsula. Journal of Petrological Society of Korea, 19, 269-281.
22	Park, Y.S., Kim, S.W., Kee, W.-S., Jeong, Y.-J., Yi, K., and Kim, J., 2009, Middle Jurassic tectono-magmatic evolution in the southwestern margin of the Gyeonggi Massif, South Korea. Geosciences Journal, 3, 217-231.
23	Pearce, J.A., 1996, Sources and settings of granitic rocks. Episodes, 19, 120-125.
24	Kim, J.H., Kee, W.-S., and Seo, S.K., 1996, Geological structures of the Yeoryang-Imgye area, northern part of Mt. Taebaeg Region, Korea. Journal of Geological Society of Korea, 32, 1-15.
25	Pearce, J.A., Harris, N.B.W., and Tindle, A.G., 1984, Trace element discrimination diagrams for the tectonic interpretation of granitic rocks. Journal of Petrology, 25, 956-983. DOI
26	Kim, H.S. and Ree, J.-H., 2012, Permo-Triassic changes in bulk crustal shortening direction during deformation and metamorphism of the Taebaeksan Basin, South Korea using Foliation Intersection/inflection Axes: Implications for tectonic movement at the eastern margin of Eurasia during the Songrim (Indosinian) orogeny. Tectonophysics, in press, doi:http://dx.doi.org/10.1016/j.tecto.2012.08.033.
27	Kim, J.H. and Kee, W.-S., 1994, Structural characteristics of the Soonchang shear zone. Journal of Southeast Asian Earth Science, 9, 417-428. DOI ScienceOn
28	Kim, S.W., Kwon, S., Koh, H.J., Yi, K., Jeong, Y.-J., and Santosh, M., 2011, Geotectonic framework of Permo- Triassic magmatism within the Korean Peninsula. Gondwana Research, 20, 865-889. DOI ScienceOn
29	Kim, S.W., Kwon, S., and Ryu, I.-C., 2009, Geochronological constraints on multiple deformations of the Honam Shear Zone, South Korea and its tectonic implication. Gondwana Research, 16, 82-89. DOI
30	Kim, Y.-J., Cho, D.-L., and Lee, C.-S., 1998, Petrology, geochemistry and tectonic implication of the A-type Daegang granite in the Namwon area, southwestern part of the Korean Peninsula. The Korean Society of Economic and Environmental Geology, 31, 399-413.
31	Kretz, R., 1983, Symbols for rock-forming minerals. American Mineralogist, 68, 277-279.
32	Jeong, Y.-J., Cheong, C.-S., Park, C.-Y., and Shin, I.-H., 2008, Geochemistry, Isotope Properties and U-Pb Sphene Age of the Jeongeup Foliated Granite, Korea. Journal of Korean Earth Science Society, 29, 539-550. DOI ScienceOn
33	Lee, B.-J., Lee, S.-R., Cho, D.-L., and Armstrong, R., 2001, Multiple ductile shearing during the Jurassic times in Jeonju ductile shear zone, Korea. Geological Society of Korea Annual Meeting, Abstract with program, p. 35.
34	Lee, C.H., 1992, Metamorphism of the Pyeongan Supergroup in the Kangreung-Bukpyung area. Journal of the Geological Society of Korea, 28, 553-570.
35	Hong, Y.-K. and Lee, B.-J., 1989, Geochemical and microstructural studies on the Sunchang foliated granodiorite at a shear zone in SW part of the Ogcheon fold belt, Korea. Journal of Geological Society of Korea, 25, 294-311.
36	Jo, H.J., 2012, U-Pb zircon geochronology and Sr-Nd-Pb isotopic studies on Namwon, Sunchang and Daegang granites distributed in the southwestern part of the Korean Peninsula. M. S. thesis, Pukyong National University, Busan, Korea, 58 p.
37	Khim, Y.H., Hwang, J.H., and Kim, S.W., 2012, Geological structures of the northern Gangneung coalfield. Journal of the Geological Society of Korea, 48, 131-147.
38	Kim, C.-B., Chang, H.-W., and Turek, A., 2003, U-Pb zircon ages and Sr-Nd-Pb isotopic compositions for Permian-Jurassic plutons in the Ogcheon belt and Ryeongnam massif, Korea: Tectonic implications and correlation with the China Qinling-Dabie belt and the Japan Hida belt. The Island Arc, 12, 366-382. DOI ScienceOn
39	Kim, H.S., 2012, Metamorphism and deformation of the late Paleozoic Pyeongan Supergroup in the Taebaeksan Basin: Reviews on the Permo-Triassic Songrim Orogeny. Journal of Petrological Society of Korea, 21, 151-171. DOI
40	Kim, H.S. and Ree, J.-H., 2010. P-T modeling of kyanite and sillimanite paramorphs growth after andalusite in late Paleozoic Pyeongan Supergroup, South Korea: implication for metamorphism during the Mesozoic tectonic evolution. Lithos, 118, 269-286. DOI
41	Cho, D.-L., Kee, W.-S., and Suzuki, K., 2007, CHIME Monazite Ages of Jurassic Foliated Granites in the Vicinity of the Gangjin Area, Korea. Journal of Petrological Society of Korea, 16, 101-115.
42	Cho, D.-L., Lee, S.R., and Armstrong, R., 2008, Termination of the Permo-Triassic Songrim (Indosinian) orogeny in the Ogcheon belt, South Korea: Occurrence of ca. 220 Ma post-orogenic alkali granites and their tectonic implications. Lithos, 105, 191-200. DOI ScienceOn
43	Cho, K.-H., Takagi, H., and Suzuki, K., 1999, CHIME monazite age of granitic rocks in the Sunchang shear zone, Korea: Timing of dextral ductile shear. Geosciences Journal, 3, 1-15. DOI
44	Choo, S.-H. and Kim, S.-J., 1985, Rb-St age determinations in the Ryeongnam massif (I). In research report of Korea Institute of Energy and Resources, KR85-24, 7-40.
45	Chough, S.K., Kwon, S.-T., Ree, J.-H., and Choi, D.-K., 2000, Tectonic and sedimentary evolution of the Korean Peninsula: a review and new view. Earth Science Reviews, 52, 175-235. DOI ScienceOn
46	Cluzel, D., 1991, Late Paleozoic to early Mesozoic geodynamic evolution of the Circum-Pacific orogenic belt in South Korea and Southwest Japan. Earth and Planetary Science Letters, 108, 289-305.
47	Frost, B.R., Barnes, C.G., Collins, W.J., Arculus, R.J., Ellis, D.J., and Frost, C.D., 2001, A geochemical classification for granitic rocks. Journal of Petrology, 42, 2033-2048. DOI
48	Furhman, M.L. and Lindsley, D.H., 1988, Ternary-feldspar modeling and thermometry. American Mineralogist, 73, 201-215.
49	Chang, T.W. and Lee, M.K., 1996a, Fabric development of granite mylonites in the Sunchang shear zone: 1. Grain size reduction. Journal of the Geological Society of Korea, 32, 421-430.
50	Gutierrez-Alonso, G., Fernandes-Suarez, J., Jeffries, T.E., Johnston, S.T., Pastor-Galan, D., Murphy, J.B., Franco, M.P., and Gonzalom J.C., 2011, Diachronous postorogenic magmatism within a developing orocline in Iberia, European Variscides. Tectonics, 30, TC5008, doi:10.1029/2010TC002845.
51	Chang, T.W. and Lee, M.K., 1996b, Fabric development of granite mylonites in the Sunchang shear zone: 2. Fabric. Journal of the Geological Society of Korea, 32, 500-508.
52	Cheong, C.-S. and Chang, H.-W., 1996, Tectonomagmatism, -metamorphism, and -mineralization of the central Ohcheon belt, Korea (I): Sr, Nd and Pb isotopic systematics and geochemistry of granitic rocks in the Boeun area. Journal of the Geological Society of Korea, 32, 91-116.
53	Cheong, C.-S., Kee, W.-S., Jeong, Y.-J., and Jeong, K.-Y., 2006, Multiple deformations along the Honam shear zone in southwestern Korea constrained by Rb-Sr dating of synkinematic fabrics: Implications for the Mesozoic tectonic evolution of northeastern Asia. Lithos, 87, 289-299. DOI