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地球物理学报 2015

柴达木盆地现今大地热流与晚古生代以来构造-热演化

DOI: 10.6038/cjg20151021, PP. 3687-3705

李宗星,高俊,郑策,刘成林,马寅生,赵为永

Keywords: 地温梯度,大地热流,裂变径迹,构造-热演化,柴达木盆地

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Abstract:

依据钻孔系统稳态测温、静井温度资料与实测热导率数据分析了柴达木盆地地温场分布特征,建立了柴达木盆地热导率柱,新增了17个大地热流数据.柴达木盆地现今地温梯度介于17.1~38.6℃·km-1,平均为28.6±4.6℃·km-1,大地热流介于32.9~70.4mW·m-2,平均55.1±7.9mW·m-2.盆地不同构造单元地温场存在差异,昆北逆冲带、一里坪坳陷属于"高温区",祁南逆冲带属于"中温区",三湖坳陷、德令哈坳陷及欧龙布鲁克隆起属于"低温区",盆地现今地温场分布特征受控于地壳深部结构、盆地构造等因素.以现今地温场为基础,采用磷灰石、锆石裂变径迹年龄分布特征定性分析与径迹长度分布数据定量模拟相结合,研究了柴达木盆地晚古生代以来的沉积埋藏、抬升剥蚀和热演化史,并结合区域构造背景,对柴达木盆地构造演化过程进行了探讨,研究表明柴达木盆地晚古生代以来经历了六期(254.0—199Ma,177—148.6Ma,87—62Ma,41.1—33.6Ma,9.6—7.1Ma,2.9—1.8Ma)构造运动,六期构造事件与研究区构造演化的动力学背景相吻合.其中白垩纪末期(87—62Ma)的构造事件导致了柴达木盆地东部隆升并遭受剥蚀,欧龙布鲁克隆起形成雏形,柴达木盆地北缘在弱挤压环境下形成坳陷盆地;中新世末的两期构造事件(9.6—7.1Ma和2.9—1.8Ma)使柴达木盆地遭受强烈挤压,盆地快速隆升,构造变形强烈,基本形成现今的构造面貌.

References

[1]	Armstrong P A. 2005. Thermochronometers in sedimentary basins. Reviews in Mineralogy & Geochemistry,58(1): 499-525.
[2]	Bellemans F,De Corte F,Van Den Haute P. 1995. Composition of SRM and CN U-doped glasses: Significance for their use as thermal neutron fluence monitors in fission track dating. Radiation Measurements,24(2): 153-160.
[3]	Brandon M T, Roden-Tice M K, Garver J I. 1998. Late Cenozoic exhumation of the Cascadia accretionary wedge in the Olympic Mountains, northwest Washington State. Geol. Soc. Am. Bull., 110(8): 985-1009.
[4]	Brandon M T. 2002. Decomposition of mixed grain age distributions using binomfit. On Track, 24: 13-18.
[5]	Chen H L, Chen S Q, Lin X B. 2014. A review of the Cenozoic tectonic evolution of Pamir syntax. Advances in Earth Science (in Chinese), 29(8): 890-902.
[6]	Chen M X. 1989. Method for determining terrestrial heat flow in Meso-Cenozoic sedimentary basins. Chinese Journal of Geology (in Chinese), (2): 151-161.
[7]	Corrigan J. 1991. Inversion of apatite fission track data for thermal history information. Journal of Geophysical Research, 96(B6): 10347-10360.
[8]	Cui J P, Ren Z L, Xiao H, et al. 2007. Study on temperature distribution and controlling factors in the Hai Lar Basin. Chinese Journal of Geology (in Chinese), 42(4): 656-665.
[9]	Feng C G, Liu S W, Wang L S, et al. 2009. Present-day geothermal regime in Tarim basin, northwest China. Chinese Journal of Geophysics (in Chinese), 52(11): 2752-2762, doi: 10.3969/j.issn.0001-5733.2009.11.010.
[10]	Galbraith R F. 1984. On statistical estimation in fission track dating. Journal of the International Association for Mathematical Geology, 16(7): 653-669.
[11]	Gallagher K, Brown R, Johnson C. 1998. Fission track analysis and its application to geological problems. Annual Review of Earth and Planetary Sciences, 26: 519-572.
[12]	Gao C, Liu J, Li D W, et al. 2014. The constraints of the fission track thermochronology on active time of the Southern Tibetan Detachment System in Cho Oyu, Tibet. Earth Science Frontiers (in Chinese), 21(6): 372-380.
[13]	Gao J P, Fang X M, Song C H, et al. 2011. Tectonic-Thermo events of Northern Tibetan Plateau: Evidence from detrital apatite fission track data in Western Qaidam Basin. Journal of Jilin University (Earth Science Edition) (in Chinese), 41(5): 1466-1475.
[14]	Ge X H, Liu Y J, Ren S M, et al. 2001. Re-understanding on some academic problems of the Altun fault. Chinese Journal of Geology (in Chinese), 36(3): 319-325.
[15]	Gleadow A J W, Duddy I R, Lovering J F. 1983. Fission track analysis: A new tool for the evaluation of thermal histories and hydrocarbon potential. APEA J., 23: 93-102.
[16]	Gleadow A J W, Duddy I R, Green P F, et al. 1986. Confined fission track lengths in apatite: A diagnostic tool for thermal history analysis. Contrib. Mineral. Petrol., 94(4): 405-415.
[17]	Green P F. 1981. A new look at statistics in fission-track dating. Nucl. Tracks, 5(1-2): 77-86.
[18]	Green P F, Duddy I R, Laslett G M, et al. 1989. Thermal annealing of fission tracks in apatite 4. Quantitative modelling techniques and extension to geological timescales. Chem. Geol., 79(2): 155-182.
[19]	He L J, Wang K L, Xiong L P, et al. 2001. Heat flow and thermal history of the South China Sea. Physics of the Earth and Planetary Interiors, 126(3-4): 211-220.
[20]	He L J, Xiong L P, Wang K L. 2002. Heat flow and thermal modeling of the Yinggehai Basin, South China Sea. Tectonophysics, 351(3): 245-253.
[21]	Hu S B, He L J, Wang J Y. 2000. Heat flow in the continental area of China: a new data set. Earth Planet. Sci. Lett., 179(2): 407-419.
[22]	Hurford A J, Green P F. 1982. A user''s guide to fission track dating calibration. Earth Planet. Sci. Lett., 59(2): 343-354.
[23]	Hurford A J, Green P F. 1983. The zeta age calibration of fission-track dating. Chemical Geology, 41: 285-317.
[24]	Hurford A J. 1990. Standardization of fission track dating calibration: Recommendation by the Fission Track Working Group of the I. U. G. S. Subcommission on Geochronology. Chemical Geology: Isotope Geoscience Section, 80(2): 171-178.
[25]	Ketcham R A, Donelick R A, Carlson W D. 1999. Variability of apatite fission track annealing Kinetics Ⅲ: Extrapolation to geological time scales. American Mineralogist, 84: 1235-1255.
[26]	Ketcham R A. 2005. Forward and inverse modeling of low-temperature thermochronometry data. Reviews in Mineralogy and Geochemistry, 58(1): 275-314.
[27]	Li G H. 1992. Characteristics of heat fluid and thermal structure of the crust in the Qaidam Basin (in Chinese). Beijing: Institute of Geology, Chinese Academy of Sciences.
[28]	Li Y H, Wu Q J, An Z H, et al. 2006. The Poisson ratio and crustal structure across the NE Tibetan Plateau determined from receiver functions. Chinese Journal of Geophysics (in Chinese), 49(5): 1359-1368.
[29]	Li Z H, Chen G, Ding C, et al. 2014. Paleogeothermal Gradient recovery in middle of Yanshanian in northern Junggar Basin. Geological Science and Technology Information (in Chinese), 33(4): 31-36.
[30]	Li Z X, Xu M, Zhao P, et al. 2013. Geothermal regime and hydrocarbon kitchen evolution in the Jianghan Basin. Science China Earth Sciences, 56(2): 240-257.
[31]	Liu H P. 2001. Geodynamic scenario of coupled basin and mountain system. Earth Science—Journal of China University of Geosciences (in Chinese), 26(6): 581-596.
[32]	Pan Y S. 1999. Formation and uplifting of the Qinghai-Tibet plateau. Earth Science Frontiers (in Chinese), 6(3): 153-163.
[33]	Popov Y A, Pevzner S L, Pimenov V P, et al. 1999. New geothermal data from the Kola superdeep well SG-3. Tectonophysics, 306(3-4): 345-366.
[34]	Qiu N S. 2001. Research on heat flow and temperature distribution of the Qaidam Basin. Journal of China University of Mining & Technology (in Chinese), 30(4): 412-415.
[35]	Qiu N S. 2002. Tectono-thermal evolution of the Qaidam Basin, China: evidence from Ro and apatite fission track data. Petroleum Geoscience, 8(3): 279-285.
[36]	Qiu N S. 2003. Geothermal regime in the Qaidam basin, northeast Qinghai-Tibet Plateau. Geol. Mag., 140(6): 707-719.
[37]	Rao S, Hu S B, Zhu C Q, et al. 2013. The characteristics of heat flow and lithospheric thermal structure in Junggar basin, northwest China. Chinese Journal of Geophysics (in Chinese), 56(8): 2760-2770, doi: 10.6038/cjg20130824.
[38]	Ren S M, Ge X H, Liu Y J, et al. 2009. Multi-stage strike-slip motion and uplift along the Altyn Tagh fault since the Late Cretaceous. Geological Bulletin of China (in Chinese), 23(9-10): 926-932.
[39]	Ren Z L. 1993. Geothermal evolution history of the Qaidam Basin: evidence from fluid inclusions and Ro.//Zhao C Y, Liu C Y et al. eds. Developments in Oil and Gas Basin Geology (in Chinese). Xi''an: Northwestern University Press, 235-247.
[40]	Shen X J, Li G H, Wang J A, et al. 1994. Terrestrial heat flow measurement and calculation of statistical heat flow in Qaidam Basin. Chinese Journal of Geophysics (Acta Geophysica Sinica) (in Chinese), 37(1): 56-65.
[41]	Sun G Q, Su L, Wang X H, et al. 2009. Fission track evidences of tectonic evolution in west Qaidam basin. Natural Gas Industry (in Chinese), 29(2): 27-31.
[42]	Tagami T, O’Sullivan P B. 2005. Fundamentals of fission-track thermochronology. Rev. Mineral. Geochem., 58(1): 19-47.
[43]	Tang J G. 2007. tectonic evolution and its control for hydrocarbon accumulation of Mesozoic-Cenozoic multicycle superimposed reformation basin in the west of northern Qaidam basin [Ph. D. thesis] (in Chinese). Beijing: China University of Geosciences.
[44]	Tang L J, Jin Z J, Zhang M L, et al. 2000. Tectonic evolution and oil (gas) pool-forming stage in northern Qaidam Basin. Petroleum Exploration and Development (in Chinese), 27(2): 36-39.
[45]	Tang X Y, Hu S B, Zhang G C, et al. 2014. Characteristic of surface heat flow in the Pearl River Mouth Basin and its relationship with thermal lithosphere thickness. Chinese Journal of Geophysics (in Chinese), 57(6): 1857-1867, doi: 10.6038/cjg20140617.
[46]	Teng J W. 1974. Deep reflected waves and the structure of the earth crust of the eastern part of Chaidam Basin. Chinese Journal of Geophysics (Acta Geophysica Sinica) (in Chinese), 17(2): 122-135.
[47]	Teng J W, Zhang Z J, Wang G J, et al. 1999. The deep internal dynamical processes and new model of continental-continental collision in Himalayan collision orogenic zone. Chinese Journal of Geophysics (in Chinese), 42(4): 481-494.
[48]	Wang F, Luo Q H, Li Q, et al. 2001. The cooling event around 30 Ma in northern edge of Qaidam Basin-Constrains from 40Ar/39Ar and Fission Track Thermochronology. Bulletin of Mineralogy Petrology and Geochemistry (in Chinese), 20(4): 228-230.
[49]	Wang H Z. 1982. The main stages of crustal development of China. Earth Science—Journal of Wuhan College of Geology (in Chinese), (3): 155-177.
[50]	Wang H Z. 1985. Atlas of the Palaeogeography of China (in Chinese). Beijing: China Map Publishing House.
[51]	Wang J, Huang S Y, Huang G S, et al. 1990. Basic Characteristics of China Temperature Distribution (in Chinese). Beijing: Seismological Press, 147-155.
[52]	Wang J Y, Huang S P. 1990. Compilation of heat flow data in the continental area of China (2th Edition). Seismology and Geology (in Chinese), 12(4): 351-363, 366.
[53]	Wang S M, Ma C Q, Se Z B, et al. 2008. Apatite fission track analyses of Cenozoic sedimentary source and basin thermal history in West Qaidam Basin. Geological Science and Technology Information (in Chinese), 27(5): 29-36.
[54]	Wang X M, Zhong D L, Wang Y. 2008. A case of application using apatite fission track to restrict the time of brittle fault movement. Progress in Geophysics (in Chinese), 23(5): 1444-1455.
[55]	Xu Z Q, Yang J T, Li H B, et al. 2006. The Qinghai-Tibet Plateau and continental dynamics: A review on terrain tectonics, collisional orogenesis, and processes and mechanisms for the rise of the plateau. Geology in China (in Chinese), 33(2): 221-238.
[56]	Yang C, Chen Q H, Ren L Y, et al. 2012. Tectonic Units of the Qaidam Basin. Journal of Southwest Petroleum University (Science & Technology Edition) (in Chinese), 34(1): 25-33.
[57]	Yang S C, Hu S B, Cai D S, et al. 2004. Present-day heat flow, thermal history and tectonic subsidence of the East China Sea Basin. Marine and Petroleum Geology, 21(9): 1095-1105.
[58]	Yin A, Dang Y Q, Wang L C, et al. 2008. Cenozoic tectonic evolution of Qaidam basin and its surrounding regions (Part 1): The southern Qilian Shan-Nan Shan thrust belt and northern Qaidam basin. Geological Society of America Bulletin, 120(7-8): 813-846.
[59]	Yu X Q, Liu J L, Zhang D H, et al. 2013. Uprising period and elevation of the Wenyu granitic pluton in the Xiaoqinling district, Central China. Chinese Science Bulletin, 58(35): 4459-4471.
[60]	Yuan Y S, Zhu W L, Mi L J, et al. 2009. "Uniform geothermal gradient" and heat flow in the Qiongdongnan and Pearl River Mouth Basins of the South China Sea. Marine and Petroleum Geology, 26(7): 1152-1162.
[61]	Zhang P Z, Zheng D W, Yin G M, et al. 2006. Discussion on late Cenozoic growth and rise of northeastern margin of the Tibetan plateau. Quaternary Sciences (in Chinese), 26(1): 5-13.
[62]	Zhang Y C, Hu J J, Liu C F. 1990. The Basic Characteristic of Earth Temperature and its Relationship with Oil and Gas in Qaidam Basin (in Chinese). Beijing: China Building Industry Press, 14-46.
[63]	Zhao G Z, Tang J, Zhan Y, et al. 2004. A study on the relationship between the electrical structure of the crust and the deformation of the block in the northeastern margin of the Qinghai Tibet Plateau. Science in China: Ser. D (in Chinese), 34(10): 908-918.
[64]	Zhao H G, Liu C Y. 2003. Detachment gliding structures of Langgu sag. Journal of Northwest University (Natural Science Edition)(in Chinese),33(3): 315-319.
[65]	Zhao J M, Tang W, Li Y S, et al. 2006. Lithospheric density and geomagnetic intensity in northeastern margin of the Tibetan plateau and tectonic implications. Earth Science Frontiers (in Chinese), 13(5): 391-400.
[66]	Zheng M L, Li M J, Cao C C, et al. 2004. Characteristics of structures of various levels in the Qaidam Cenozoic Basin. Acta Geologica Sinica (in Chinese), 78(1): 26-35.
[67]	Zhou J X, Xu F Y, Hu Y. 2003. Mesozoic and Cenozoic tectonism and its control on hydrocarbon accumulation in the northern Qaidam Basin of China. Acta Petrolei Sinica (in Chinese), 24(1): 19-24.
[68]	Zhu L P, Helmberger D V. 1998. Moho offset across the northern margin of the Tibetan Plateau. Science, 281(5380): 1170-1172.
[69]	Zuo Y H, Qiu N S, Zhang Y, et al. 2011. Geothermal regime and hydrocarbon kitchen evolution of the offshore Bohai Bay Basin, North China. AAPG Bulletin, 95(5): 749-769.

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