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Quaternary structural partitioning within the rigid Tarim plate inferred from magnetostratigraphy and sedimentation rate in the eastern Tarim Basin in China

Published online by Cambridge University Press:  20 January 2017

Hong Chang
Affiliation:
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi'an 710075, China
Zhisheng An
Affiliation:
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi'an 710075, China
Weiguo Liu
Affiliation:
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi'an 710075, China
Hong Ao
Affiliation:
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi'an 710075, China
Xiaoke Qiang
Affiliation:
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi'an 710075, China
Yougui Song
Affiliation:
State Key Laboratory of Loess and Quaternary Geology, Institute of Earth Environment, Chinese Academy of Sciences, Xi'an 710075, China
Zhongping Lai
Affiliation:
Resources & Chemical Laboratory, Qinghai Institute of Salt Lakes, Chinese Academy of Sciences, Lanzhou 730000, China

Abstract

It has been proposed that within the Tarim Basin tectonic activity has been limited since Triassic time. However, on the basis of magnetostratigraphy from the eastern Tarim Basin, which defines the chronology of sedimentation and structural evolution of the basin, we show that the basin interior has been uplifted and partitioned during Quaternary. The magnetostratigraphy was constructed from 2228 samples that yielded acceptable inclination values. Characteristic remnant magnetization (ChRM) with both normal (N1–N11) and reversed (R1–R11) polarity was isolated by thermal demagnetization. The data correlate best with polarity chrons C3r to C1n, which range from 5.39 Ma to recent on the geological time scale 2004 (GTS2004). An abrupt decrease in the sedimentation rate is observed at 1.77 Ma in the Ls1 core. This change does not overlap with known Pleistocene climate-change events. We attribute this sedimentation rate decrease to a structurally controlled local decrease in accommodation space where basin basement uplifts occur. This period of sedimentary environmental change reveals that structural partitioning in the basement of the Tarim Basin occurred since ~ 1.77 Ma, and we speculate that tilting of the Southeast Uplift (a sub-basin unit) within the Tarim Basin began in early Pleistocene time.

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Articles
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University of Washington

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References

Ao, H., Deng, C.L., Dekkers, M.J., and Liu, Q.S. Magnetic mineral dissolution in the Pleistocene fluvial-lacustrine sediments, Nihewan Basin (North China). Earth and Planetary Science Letters 292, (2010). 191200.Google Scholar
Avouac, J.P., Tapponnier, P., Bai, M., Hou, Y., and Wang, G. Active thrusting and folding along the northeastern Tienshan, and rotation of Tarim relative to Dzungaria and Kazakhstan. Journal of Geophysical Research 98, (1993). 67556804.Google Scholar
Beaumont, C. Foreland basins. Geophysical Journal of the Royal Astronomical Society 65, (1981). 291329.Google Scholar
Besse, J., Courtillot, V., Pozzi, J.P., Westphal, M., and Zhou, Y.X. Paleomagnetic estimates of crustal shortening in the Himalayan thrusts and Zanbo suture. Nature 311, (1984). 621626.Google Scholar
Blair, T.C., and Bilodeau, W.L. Development of tectonic cyclothems in rift, pull-apart, and foreland basins: sedimentary response to episodic tectonism. Geology 16, (1988). 517520.Google Scholar
Burbank, D.W., and Beck, R.A. Model of aggradation versus progradation in the Himalayan Foreland. Geologische Rundschau 80, (1991). 623638.Google Scholar
Bureau of Geology and Mineral Resources of Xinjiang Uygur Autonomous Region, Regional Geology of Xinjiang Uygur Autonomous Region. BGMRXYAR (1993). Geological Publication House, Beijing.Google Scholar
Chang, H., Ao, H., An, Z.S., Fang, X.M., Song, Y.G., and Qiang, X.K. Magnetostratigraphy of the Suerkuli Basin indicates Pliocene (3.2 Ma) activity of the middle Altyn Tagh Fault, northern Tibetan Plateau. Journal of Asian Earth Sciences 44, (2012). 169175.Google Scholar
Chang, H., An, Z.S., Liu, W.G., Qiang, X.K., Song, Y.G., and Ao, H. Magnetostratigraphic and paleoenvironmental records for a Late Cenozoic sedimentary sequence drilled from Lop Nor in the eastern Tarim Basin. Global and Planetary Changes 80–81, (2012). 113122.CrossRefGoogle Scholar
Chen, C.M., Lu, H.F., Jia, D., and Xie, X.A. Tertiary–Quaternary sedimentation, tectonic deformation in Tarim basin and its implications to petroleum geology. Acta Sedimentologica Sinica 16, (1998). 113116. (in Chinese with abstract in English) Google Scholar
Chen, J., Burbank, D.W., Scharer, K.M., Sobel, E., Yin, J.H., Rubin, C., and Zhao, R.B. Magnetochronology of the upper Cenozoic strata in the southwestern Chinese Tian Shan: rates of Pleistocene folding and thrusting. Earth and Planetary Science Letters 195, (2002). 113130.CrossRefGoogle Scholar
Collinson, D.W. Methods in Rock Magnetism and Palaeomagnetism: Techniques and Instruments. (1983). Chapman & Hall, London.Google Scholar
Dong, Z.B., Lv, P., Qian, G.Q., Xia, X.C., Zhao, Y.J., and Mu, G.J. Research progress in China's Lop Nur. Earth-Science Reviews 111, (2012). 142153.Google Scholar
Dupont-Nivet, G., and Butler, R.F. Paleomagnetism indicates no Neogene vertical axis rotations of the northeastern Tibetan Plateau. Journal of Geophysical Research 108, (2003). 2386 CrossRefGoogle Scholar
Fang, X.M., Zhang, W.L., Meng, Q.Q., Gao, J.P., Wang, X.M., King, J., Song, C.H., Dai, S., and Miao, Y.F. High-resolution magnetostratigraphy of the Neogene Huaitoutala section in the eastern Qaidam Basin on the NE Tibetan Plateau, Qinghai Province, China and its implication on the tectonic uplift of the NE Tibetan Plateau. Earth and Planetary Science Letters 258, (2007). 293306.Google Scholar
Gao, R., Huang, D.D., Li, D.Y., Qian, G.H., Li, Y.K., Kuang, C.Y., Li, Q.S., Li, P.W., Feng, R.J., and Guan, Y. Deep seismic reflection profile across the juncture zone between the Tarim Basin and the West Kunlun Mountains. Chinese Science Bulletin 45, (2000). 22812286.Google Scholar
Garzanti, E., Baud, A., and Mascale, G. Sedimentary record of the northward flight on India and its collision with Eurasia (Ladakh, Himalay, India). Geodinamica Acta 1, (1987). 297312.CrossRefGoogle Scholar
Geomorphology Group of Xinjiang Comprehensive Investigation (GGXCI), Geomorphology of Xinjiang. (1978). Science Press, Beijing. (In Chinese) Google Scholar
Gradstein, F., Ogg, J., and Smith, A. A Geologic Time Scale 2004. (2004). Elsevier Inc., Cambridge.Google Scholar
Guo, Z.J., and Zhang, Z.C. The Geological interpretation of the forming and evolution of Lop Nur, NW China. Geological Journal of University 1, (1995). 8287. (In Chinese with English abstract) Google Scholar
Gupta, S. Tectonic control on paleovalley incision at the distal margin of the early Tertiary Alpine Foreland Basin, southeast France. Journal of Sedimentary Research 67, (1997). 10301043.Google Scholar
Hao, Y.C., Guan, S.Z., Ye, L.S., Huang, Y.Y., Zhou, Y.C., and Guan, S.Q. Neogene stratigraphy and paleogeography in the western Tarim basin. Acta Geologica Sinica 76, (2002). 289298. (in Chinese with abstract in English) Google Scholar
Heermance, R.V., Chen, J., Burbank, D.W., and Wang, C.S. Chronology and tectonic controls of Late Tertiary deposition in the southwestern Tian Shan foreland, NW China. Basin Research 19, (2007). 599632.Google Scholar
Hendrix, M.S., Dumitru, T.A., and Graham, S.A. Late-Oligocene–Early-Miocene unroofing in the Chinese Tien Shan: an early effect of the India–Asia collision. Geology 22, (1994). 487490.Google Scholar
Huang, B.C., Piper, J.D.A., Peng, S.T., Liu, T., Li, Z., Wang, Q.C., and Zhu, R.X. Magnetostratigraphic study of the Kuche Depression, Tarim Basin, and Cenozoic uplift of the Tian Shan Range, Western China. Earth and Planetary Science Letters 251, (2006). 346364.Google Scholar
Institute of Mineral Deposits, Chinese Academy of Geological Sciences (IMDCAGS). (1981). Linear Structure Map of Chinese Lands (1:6 000 000) (In Chinese). Sinomap Press, Beijing.Google Scholar
Jia, C.Z. Structural feature and law of hydrocarbon accumulation in the Tarim basin. Xinjiang Petroleum Geology 20, (1993). 177183. (in Chinese with abstract in English) Google Scholar
Jia, C.Z. Tectonic Characteristics of Tarim Basin in China (in Chinese). (1997). Petroleum Industry Publishing House, Beijing.Google Scholar
Jia, C.Z., and Wei, G.Q. Structural characteristics and petroliferous features of Tarim Basin. Chinese Science Bulletin 47 Suppl., (2002). 111.CrossRefGoogle Scholar
Jin, X.C., Wang, J., Chen, B.W., and Ren, L.D. Cenozoic depositional sequences in the piedmont of the west Kunlun and their paleogeographic and tectonic implications. Journal of Asian Earth Sciences 21, (2003). 755765.Google Scholar
Kao, H., Gao, R., Rau, R., Shi, D.N., Chen, R.Y., Guan, Y., and Wu, F.T. Seismic image of the Tarim basin and its collision with Tibet. Geology 29, (2001). 575578.Google Scholar
Kirschvink, J.L. The least squares line and plane and analysis of paleomagnetic data. Geophysical Journal of the Royal Astronomical Society 62, (1980). 699712.Google Scholar
Li, Q.C., and Xu, B.R. The characteristic and geological meaning of Curie isothermic surface under the Tarim basin. Oil Geology Prospect 34, (1999). 590594. (in Chinese with abstract in English) Google Scholar
Li, J.J., Fang, X.M., Ma, H.Z., Zhu, J.J., Pan, B.T., and Chen, H.L. Geomorphological and environmental evolution in the upper reaches of the Yellow River during the late Cenozoic. Science in China 39, (1996). 380389.Google Scholar
Li, J.J., Fang, X.M., Van der Voo, R., Zhu, J.J., Niocaill, C.M., Cao, J.X., Zhong, W., Chen, H.L., Wang, J.L., Wang, J.M., and Zhang, Y.C. Late Cenozoic magnetostratigraphy (11–0 Ma) of the Dongshanding and Wangjiashan sections in the Longzhong Basin, western China. Geologie en Mijnbouw 76, (1997). 121134.Google Scholar
Liang, K. The environmental evolution of Lake Lop Nor as seen on the remote sensing images. Remote Sensing of Environment China 2, 4 (1987). 285295. (In Chinese with abstract in English) Google Scholar
Lisiecki, L.E., and Raymo, M.E. Plio-Pleistocene climate evolution: trends and transitions in glacial cycle dynamics. Quaternary Science Reviews 26, (2007). 5669.Google Scholar
Liu, C.L., Wang, M.L., Jiao, P.C., Li, S.D., and Chen, Y.Z. Features and formation mechanism of faults and potash-forming effect in the Lop Nur Salk Lake, Xinjiang, China. Acta Geologica Sinica 80, (2006). 936943.Google Scholar
Lu, H.J., and Xiong, S.F. Magnetostratigraphy of the Dahonggou section, northern Qaidam Basin and its bearing on Cenozoic tectonic evolution of the Qilian Shan and Altyn Tagh Fault. Earth and Planetary Science Letters 288, (2009). 539550.Google Scholar
Matte, P., Tapponnier, P., Arnaud, N., Bourjot, L., Avouac, J.P., Vidal, P., Liu, Q., Pan, Y.S., and Wang, Y. Tectonics of western Tibet, between the Tarim and the Indus. Earth and Planetary Science Letters 142, (1996). 311330.Google Scholar
McCann, T., and Saintot, A. Tracing tectonic deformation using the sedimentary record: an overview. McCann, T., and Saintot, A. Tracing Tectonic Deformation Using the Sedimentary Record. (2003). 128.Google Scholar
Meng, G.X., Yan, J.Y., Lv, Q.T., Jiao, P.C., Yan, H., Liu, C.F., and Liu, C.L. New discovery of Lop Nur salt basin structure and its significance for potash deposit exploration. Mineral Deposits 29, (2010). 609615.Google Scholar
Molnar, P., and England, P. Late Cenozoic uplift of mountain ranges and global climate change: chicken or egg?. Nature 346, (1990). 2934.CrossRefGoogle Scholar
Mu, G.J., Bao, A.M., and Hao, J. Geotectonic environment of the tail-end-lakes evolution, Xinjiang, China. Arid Land Geography 24, (2001). 193200. (in Chinese with abstract in English) Google Scholar
Negredo, A.M., Replumaz, A., Villaseñor, A., and Guillot, S. Modeling the evolution of continental subduction processes in the Pamir–Hindu Kush region. Earth and Planetary Science Letters 259, (2007). 212225.Google Scholar
Nott, J., and Roberts, R.G. Time and process rates over the past 100 m.y.: a case for dramatically increased landscape denudation rates during the late Quaternary in northern Australia. Geology 24, (1996). 883887.Google Scholar
Rowley, D.B., and Currie, B.S. Paleo-altimetry of the late Eocene to Miocene Lunpola basin, central Tibet. Nature 439, (2006). 677681.Google Scholar
Scharer, K.M., Burbank, D.W., Chen, J., Weldon, R.J. II Konematic models of fluvial terraces over active detachment fold: constraints on the growth mechanism of the Kashi–Atushi fold system, Chinese Tian Shan. Geological Society of America Bulletin 118, (2006). 10061028.Google Scholar
Searle, M.P., Windley, B.F., Coward, M.P., Cooper, D.J.W., Rex, A.J., Rex, D., Li, T.D., Xiao, X.C., Jan, M.Q., Thakur, V.C., and Kumar, S. The closing of Tethys and the tectonics of the Himalaya. Geological Society of America Bulletin 98, (1987). 678701.Google Scholar
Sklar, L.S., and Dittrich, W.E. Sediment and rock strength controls on river incision into bedrock. Geology 29, (2001). 10871090.2.0.CO;2>CrossRefGoogle Scholar
Sobel, E.R., Chen, J., and Heermance, R.V. Late Oligocene–Early Miocene initiation of shortening in the Southwestern Chinese Tian Shan: implications for Neogene shortening rate variations. Earth and Planetary Science Letters 247, (2006). 7081.CrossRefGoogle Scholar
Sun, Z.C., Feng, X.J., Li, D.M., Yang, F., Qu, Y.H., and Wang, H.J. Cenozoic Ostracoda and palaeoenvironments of the northeastern Tarim Basin, western China. Palaeogeography Palaeoclimatology Palaeoecology 148, (1999). 3750.Google Scholar
Sun, J.M., Zhang, L.Y., Deng, C.L., and Zhu, R.X. Evidence for enhanced aridity in the Tarim Basin of China since 5.3 Ma. Quaternary Science Reviews 27, (2008). 10121023.Google Scholar
Tankard, A.J., Welsink, H.J., and Jenkins, W.A.W. Structural styles and stratigraphy of the Jeanne d'Arc Basin, Grand Banks of Newfoundland. Tankard, A.J., and Balkwill, H.R. Extensional Tectonics and Stratigraphy of North Atlantic Margins. AAPG Memoir 46, (1989). 265282.Google Scholar
Tapponnier, P., Xu, Z.Q., Roger, F., Meyer, B., Arnaud, N., Wittlinger, G., and Yang, J.S. Oblique stepwise rise and growth of the Tibetan Plateau. Science 294, (2001). 16711677.Google Scholar
Wang, S. A preliminary study on neotectonic movement in the Lop Nur and surrounding regions. Xia, X. Scientific Exploration and Study of the Lop Nor. (1987). Science Press, Beijing. 3751.Google Scholar
Wang, W. The geological history of the Lop Nor and surrounding regions. Xia, X. Scientific Exploration and Study of the Lop Nor. (1987). Science Press, Beijing. 1619.Google Scholar
Wang, M., and Liu, C. Saline Lake Potash Resources in the Lop Nur. (2001). Geological Publishing House, Beijing.Google Scholar
Wang, L.S., Li, C., and Yang, C. The lithospheric thermal structure beneath Tarim Basin, western China. Acta Geophysica Sinica 39, 6 (1996). 794803. (in Chinese with abstract in English) Google Scholar
Wang, E., Van, J.L., and Liu, J.Q. Late Cenozoic geological evolution of the foreland basin bordering the West Kunlun range in Pulu area: constraints on timing of uplift of northern margin of the Tibetan Plateau. Journal of Geophysical Research 108, (2003). 2401 http://dx.doi.org/10.1029/2002JB001877Google Scholar
Wang, E., Xu, F.Y., Zhou, J.X., Wan, J.L., and Burchfield, B.C. Eastward migration of the Qaidam basin and its implications for Cenozoic evolution of the Altyn Tagh fault and associated river system. Geological Society of America Bulletin 118, (2006). 349365.Google Scholar
Wang, C.S., Zhao, X.X., Liu, Z.F., Lippert, P., Graham, S.A., Coe, R.S., Yi, H.S., Zhu, L.D., Liu, S., and Li, Y.L. Constraints on the early uplift history of the Tibetan Plateau. Proceedings of the National Academy of Sciences of the United States of America 105, (2008). 49874992.CrossRefGoogle ScholarPubMed
Windley, B.F., Allen, M.B., Zhang, C., Zhao, Z.Y., and Wang, G.R. Paleozoic accretion and Cenozoic redeformation of the Chinese Tien Shan Ranges, central Asia. Geology 18, (1990). 128131.2.3.CO;2>CrossRefGoogle Scholar
Wittlinger, G., Tapponnier, P., Poupinet, G., Jiang, M., Shi, D.N., Herquel, G., and Masson, F. Topographic evidence for localized lithospheric shear along the Altyn Tagh Fault. Science 28, (1998). 7476.Google Scholar
Xiao, X.C., Liu, X., Gao, R. et al. The crustal structure and tectonic evolution of southern Xinjiang China. (2004). The Commercial Press, Beijing. 1270.Google Scholar
Xiao, G.Q., Guo, Z.T., Dupont-Nivet, G., Lu, H.Y., Wu, N.Q., Ge, J.Y., Hao, Q.Z., Peng, S.Z., Li, F.J., Abels, H.A., and Zhang, K.X. Evidence for northeastern Tibetan Plateau uplift between 25 and 20 Ma in the sedimentary archive of the Xining Basin, Northwestern China. Earth and Planetary Science Letters 317–318, (2012). 185195.CrossRefGoogle Scholar
Yan, S., and Mu, G.J. The environmental evolution of the Tarim Basin in late Cenozoic era. Arid Land Geography 13, (1990). 19. (in Chinese with abstract in English) Google Scholar
Yan, S., Mu, G.J., Xu, Y.Q., and Zhao, Z.H. Quaternary environmental evolution of the Lop Nur region, China. Acta Geographica Sinica 53, (1998). 332340. (in Chinese with abstract in English) Google Scholar
Yang, Y.Q., and Liu, M. Cenozoic deformation of the Tarim plate and the implications for mountain building in the Tibetan Plateau and the Tian Shan. Tectonics 21, (2002). 1059 http://dx.doi.org/10.1029/2001TC001300Google Scholar
Yin, A., Rumelhart, P.E., Butler, R., Cowgill, E., Harrison, T.M., Foster, D.A., Ingersoll, R.V., Zhang, Q., Zhou, X.Q., Wang, X.F., Hanson, A., and Raza, A. Tectonic history of the Altyn Tagh fault system in northern Tibetan. Geological Society of America Bulletin 114, (2002). 12571295.Google Scholar
Yin, A., Dang, Y.Q., Zhang, M., Chen, X.H., and McRivette, M.W. Cenozoic tectonic evolution of the Qaidam basin and its surrounding regions (Part 3): structural geology, sedimentation, and regional tectonic reconstruction. Geological Society of America Bulletin 120, (2008). 847876.Google Scholar
Zachos, J., Pagani, M., Sloan, L., Thomas, E., and Billups, K. Trends, rhythms, and aberrations in global climate 65 Ma to present. Science 292, (2001). 686693.Google Scholar
Zhang, P.Z., Molnar, P., and Downs, W.R. Increased sedimentation rates and grain sizes 2–4 Myr ago due to the influence of climate change on erosion rates. Nature 410, (2001). 891897.Google Scholar
Zheng, H.B., Powell, C.M., An, Z.S., Zhou, J., and Dong, G.R. Pliocene uplift of the northern Tibetan Plateau. Geology 28, (2000). 715718.Google Scholar
Zhong, W., Tuerxun, Keyimu, Shu, Q., and Wang, L.G. Paleoclimatic and paleoenvironmental evolution since about 25 Ka BP in the Taitema Lake area, South Xinjiang. Arid Land Geography 28, (2005). 183187. (in Chinese with abstract in English) Google Scholar
Zijderceld, J.D.A. A.C. demagnetization of rock: analysis of results. Collinson, D.W., Creer, K.M., and Runcorn, S.K. Methods in Paleomagnetism. (1967). Elsevier, New York. 254286.Google Scholar