Abstract
River capture is of great significance to landform evolution and hominine migration. In the Qinling-Daba Mountains, there is a viewpoint that Jialing River captured Hanjiang River, but this is still controversial. In this paper, we discuss the drainage evolution processes in intermountain basins at the Qinling-Daba Mountains based on a combination of detrital zircon U-Pb geochronology and geomorphic indexes. We suggest that the Hanjiang River gradually captured the Jialing River from east to west, accompanied by the evolution of the ancient Yangtze River. In terms of geomorphic evidences, wide valleys did not match with discharge, and a series of wind gaps developed in the Shiquan-Ankang basin. In addition, the valley shapes and width-to-height ratios (Vf) indicate two possible rapid incisions. The hypsometric integrals (HI) reflect that the landform gradually changes from the old stage to the youth stage from west to east. The χ values show that the drainage divide is moving to the side of the Yuehe River, and the Yuehe River is gradually shrinking. According to the sedimentary records, the zircon U-Pb age distributions indicate the provenance change. The high-altitude terraces show three age peaks (200–250, 400–505, and 700–900 Ma), with the dominant Indosinian age peak (200–250 Ma), while the modern fluvial sediments only show a single peak of Jinning (700–900 Ma). These data show that there are two major river captures: (1) The ancient Hanjiang River cut through the regional compression ridge, and then captured the Hanzhong Basin river system (a part of the ancient Jialing river system) from east to west, and (2) The southern tributary captured the trunk with the uplift of the divide in the Shiquan-Ankang Basin, forming the modern drainage pattern in the upper Hanjiang River. The activities of the regional strike-slip fault, and the associated compression uplift played a key role in the river captures, the drainage evolution, and related landforms in the Shiquan-Ankang basin. In addition, it is shown that the evolution of the upper tributary basins lagged behind the response of the trunk channel to the tectonic activities and river captures. The interconnected wide valleys caused by river capture may have provided convenient geomorphological conditions for human migration into the Qinling-Daba Mountains along those river valleys.
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References
Achterberg E, Ryan C, Jackson S, Griffin W. 2001. LA-ICP-MS in the Earth Sciences-Appendix 3, data reduction software for LA-ICP-MS. Short Course Series, 29: 239–243
Andersen T. 2002. Correction of common lead in U-Pb analyses that do not report 204Pb. Chem Geol, 192: 59–79
Antón L, De Vicente G, Muñoz-Martín A, Stokes M. 2014. Using river long profiles and geomorphic indices to evaluate the geomorphological signature of continental scale drainage capture, Duero basin (NW Iberia). Geomorphology, 206: 250–261
Bishop P. 1995. Drainage rearrangement by river capture, beheading and diversion. Prog Phys Geogr-Earth Environ, 19: 449–473
Bonnet S. 2009. Shrinking and splitting of drainage basins in orogenic landscapes from the migration of the main drainage divide. Nat Geosci, 2: 766–771
Bull W B, McFadden L D. 1977. Tectonic geomorphology north and south of the Garlock Fault, California. In: Morali A, Olive O, Vidailhet M, Benz-Lemoine E, eds. Geomorphology in Arid Regions. Routledge. 115–138
Cai Z Y, Luo H, Xiong X L, Wu D K, Wu X L, Sun S C, Yang J. 2006. A discussion on the age of the meta-sedimentary rocks in the upper part of the Wudang Group constrained by the grain-zircon U-Pb dating (in Chinese). J Stratigr, 30: 60–63
Castelltort S, Goren L, Willett S D, Champagnac J D, Herman F, Braun J. 2012. River drainage patterns in the New Zealand Alps primarily controlled by plate tectonic strain. Nat Geosci, 5: 744–748
Chen H, Hu J M, Wu G L, Tian M. 2014. Late Mesozoic intra-continental deformation and lateral extrusion in central segment of Southern Qinling belt (in Chinese). J Jilin Univ-Earth Sci Ed, 44: 1906–1927
Clark M K, Schoenbohm L M, Royden L H, Whipple K X, Burchfiel B C, Zhang X, Tang W, Wang E, Chen L. 2004. Surface uplift, tectonics, and erosion of eastern Tibet from large-scale drainage patterns. Tectonics, 23: TC1006
Clift P D, Blusztajn J. 2005. Reorganization of the western Himalayan river system after five million years ago. Nature, 438: 1001–1003
Cox R T. 1994. Analysis of drainage-basin symmetry as a rapid technique to identify areas of possible Quaternary tilt-block tectonics: An example from the Mississippi Embayment. Geol Soc Am Bull, 106: 571
Craw D, Upton P, Burridge C P, Wallis G P, Waters J M. 2016. Rapid biological speciation driven by tectonic evolution in New Zealand. Nat Geosci, 9: 140–144
Cui J, Han F, Zhang S, Wang G, Wang X, Peng H, Wang J,Guo Q, Peng A, Dui H. 2010. Zircon SHRIMP U-Pb dating and the tectonic significance of the Xixiang Group in Southern Qinling. Geol Shaanxi, 28: 53–58
Dong Y, Liu X, Santosh M, Zhang X, Chen Q, Yang C, Yang Z. 2011. Neoproterozoic subduction tectonics of the northwestern Yangtze Block in South China: Constrains from zircon U-Pb geochronology and geochemistry of mafic intrusions in the Hannan Massif. Precambrian Res, 189: 66–90
Dong Y, Liu X, Santosh M, Chen Q, Zhang X, Li W, He D, Zhang G. 2012. Neoproterozoic accretionary tectonics along the northwestern margin of the Yangtze Block, China: Constraints from zircon U-Pb geochronology and geochemistry. Precambrian Res, 196-197: 247–274
Fan N, Chu Z, Jiang L, Hassan M A, Lamb M P, Liu X. 2018. Abrupt drainage basin reorganization following a Pleistocene river capture. Nat Commun, 9: 3756
Flint J J. 1974. Stream gradient as a function of order, magnitude, and discharge. Water Resour Res, 10: 969–973
Gan J S, Liu S W, Li Y J. 2002. Tectonic developing characteristics of Yuehe pull-apart basin in South Qinling area (in Chinese). J Geodesy Geodyn, 22: 101–105
Geng Y. 2010. SHRIMP U-Pb zircon geochronology and geochemistry study of Neoproterozoic granites in the northern margin of Yangtze continent. Dissertation for Master’s Degree. Beijing: China University of Geosciences
Goren L, Willett S D, Herman F, Braun J. 2014. Coupled numerical-analytical approach to landscape evolution modeling. Earth Surf Proc Land, 39: 522–545
Han Z, Sinclair H D, Li Y, Wang C, Tao Z, Qian X, Ning Z, Zhang J, Wen Y, Lin J, Zhang B, Xu M, Dai J, Zhou A, Liang H, Cao S. 2019. Internal drainage has sustained low-relief Tibetan landscapes since the early Miocene. Geophys Res Lett, 46: 8741–8752
Howard A D. 1965. Geomorphological systems-Equilibrium and dynamics. Am J Sci, 263: 302–312
Howard A D. 1967. Drainage analysis in geologic interpretation: A summation. AAPG Bull, 51: 2246–2259
Howard A D, Kerby G. 1983. Channel changes in badlands. Geol Soc Am Bull, 94: 739–752
Hu J M, Meng Q R, Chen H, Wu G L, Qu H J, Gao W and Chen W. 2011. Tectonic evolution and implication of Ningshan Fault in the central part of Qinling Orogen (in Chinese). Acta Petrol Sin, 27: 657–671
Hu J M, Zhao G C, Ma G L, Zhang S Q, Gao D S. 2004. Paleozoic extensional tectonics of the Wudang block in the Qinling Orogen, China (in Chinese). Chin J Geol, 39: 305–319, 457
Hu Z B, Pan B T, Bridgland D, Vandenberghe J, Guo L Y, Fan Y L, Westaway R. 2017. The linking of the upper-middle and lower reaches of the Yellow River as a result of fluvial entrenchment. Quat Sci Rev, 166: 324–338
Huang W W, Qi G Q. 1987. Preliminary observation of Liangshan Paleolithic Site (in Chinese). Acta Anthropol Sin, 6: 236–244
Jackson S E, Pearson N J, Griffin W L, Belousova E A. 2004. The application of laser ablation-inductively coupled plasma-mass spectrometry to in situ U-Pb zircon geochronology. Chem Geol, 211: 47–69
Johnson D W. 1907. river capture in the tallulah district, georgia. Science, 25: 428–432
Keller E A, Pinter N. 2002. Active Tectonics: Earthquakes, Uplift and Lansdcape. 2nd ed. Upper Saddle River: Prentice Hall. 362
Kirby E, Whipple K X. 2012. Expression of active tectonics in erosional landscapes. J Struct Geol, 44: 54–75
Kirby E, Whipple K X, Tang W, Chen Z. 2003. Distribution of active rock uplift along the eastern margin of the Tibetan Plateau: Inferences from bedrock channel longitudinal profiles. J Geophys Res, 108: 2217
Lai S C, Li Y F, Qin J F. 2007. Geochemistry and LA-ICP-MS zircon U-Pb dating of the Dongjiahe ophiolite complex from the western Bikou terrane. Sci China Ser D-Earth Sci, 50: 305–313
Laskowski A K, Orme D A, Cai F, Ding L. 2019. The Ancestral Lhasa River: A Late Cretaceous trans-arc river that drained the proto-Tibetan Plateau. Geology, 47: 1029–1033
Li H K, Lu S N, Chen Z H, Xiang Z Q, Zhou HY, Hao G J. 2003. Zircon UPb geochronology of rift-type volcanic rocks in Yaolinghe Group in the South Qinling orogen (in Chinese). Geol Bull China, 22: 775–781
Li J H, Zhang Y Q, Dong S W, Shi W, Li H L. 2010. Apatite fission track thermochronologic constraint on Late mesozoic uplifting of the Fenghuangshan basement uplift (in Chinese). Chin J Geol, 45: 969–986
Li J H, Zhang Y Q, Xu X B, Dong S W, Li T D. 2012. Zircon U-Pb LAICP- MS Dating of Fenghuangshan Pluton in Northern Daba Mountains and Its Implications to Tectonic Settings (in Chinese). Geol Rev, 58: 581–593
Ling W L, Gao S, Ouyang J P, Zhang B R, Li H M. 2002. Age and tectonic setting of Xixiang Group: constraints of isotopic chronology and geochemistry. Sci China Ser D-Earth Sci, 32: 101–112
Ling W L, Ren B F, Duan R C, Liu X M, Mao X W, Peng L H, Liu Z X, Cheng J P, Yang H M. 2008. Timing of the Wudangshan, Yaolinghe volcanic sequences and mafic sills in South Qinling: U-Pb zircon geochronology and tectonic implication. Chin Sci Bull, 53: 2192–2199
Liu S, Li J, Stockli D F, Song C, Nie J, Peng T, Wang X, He K, Hui Z, Zhang J. 2015. Late Tertiary reorganizations of deformation in northeastern Tibet constrained by stratigraphy and provenance data from eastern Longzhong Basin. J Geophys Res-Solid Earth, 120: 5804–5821
Liu Z H, Chen L Y, Qu W, Hu J, Liu X C. 2019. Early Mesozoic Metamorphism, Anataxis and Deformation of Foping Area in South Qinling Belt: Constrains from U-Pb Zircon Dating (in Chinese). Acta Geosci Sin, 40: 545–571
Liu Z H, Luo M, Chen L Y, Qu W, Liu X C. 2018. Stratigraphic framework and provenance analysis in the Foping area, the South Qinling tectonic belt: Constraints from LA-ICP-MS U-Pb dating of detrital zircons from the metasedimentary rocks (in Chinese). Acta Petrol Sin, 34: 1484–1502
Meng Q R. 2017. Origin of the Qinling Mountains. Sci China Earth Sci, 47: 412–420
Menier D, Mathew M, Pubellier M, Sapin F, Delcaillau B, Siddiqui N, Ramkumar M, Santosh M. 2017. Landscape response to progressive tectonic and climatic forcing in NW Borneo: Implications for geological and geomorphic controls on flood hazard. Sci Rep, 7: 457
Pearce N J G, Perkins W T, Westgate J A, Gorton M P, Jackson S E, Neal C R, Chenery S P. 1997. A compilation of new and published major and trace element data for NIST SRM 610 and NIST SRM 612 glass reference materials. Geostand Geoanal Res, 21: 115–144
Perron J T, Royden L. 2013. An integral approach to bedrock river profile analysis. Earth Surf Proc Land, 38: 570–576
Perron J T, Richardson P W, Ferrier K L, Lapôtre M. 2012. The root of branching river networks. Nature, 492: 100–103
Pike R J, Wilson S E. 1971. Elevation-relief ratio, hypsometric integral, and geomorphic area-altitude analysis. Geol Soc Am Bull, 82: 1079–1084
Prince P S, Spotila J A, Henika W S. 2011. Stream capture as driver of transient landscape evolution in a tectonically quiescent setting. Geology, 39: 823–826
Pritchard D, Roberts G G, White N J, Richardson C N. 2009. Uplift histories from river profiles. Geophys Res Lett, 36: L24301
Qi W, Wang X L, Wang W H, Wang B Y, Bai D B, Zhang B. 2002. Tectonic basement of the Proterozoic era in Fenghuangshan area of Southern Qinling (in Chinese). Geol Shaanxi, 20: 9–19
Qin J, Lai S, Grapes R, Diwu C, Ju Y, Li Y. 2009. Geochemical evidence for origin of magma mixing for the Triassic monzonitic granite and its enclaves at Mishuling in the Qinling orogen (central China). Lithos, 112: 259–276
Qin J F, Lai S C, Wang J, Li Y F. 2007. High-Mg# adakitic tonalite from the Xichahe Area, South Qinling Orogenic Belt (Central China): Petrogenesis and geological implications. Int Geol Rev, 49: 1145–1158
Qin J, Lai S, Li Y. 2008a. Slab breakoff model for the Triassic Postcollisional adakitic granitoids in the Qinling Orogen, Central China: Zircon U-Pb ages, geochemistry, and Sr-Nd-Pb isotopic constraints. Int Geol Rev, 50: 1080–1104
Qin J, Lai S, Wang J, Li Y. 2008b. Zircon LA-ICPMS U-Pb age, Sr-Nd-Pb isotopic compositions and geochemistry of the Triassic Post-collisional Wulong adakitic granodiorite in the South Qinling, Central China, and its petrogenesis. Acta Geol Sin-Engl Ed, 82: 425–437
Schwanghart W, Scherler D. 2014. Short Communication: TopoToolbox 2-MATLAB-based software for topographic analysis and modeling in Earth surface sciences. Earth Surf Dynam, 2: 1–7
Seong Y B, Owen L A, Bishop M P, Bush A, Clendon P, Copland L, Finkel R C, Kamp U, Shroder John F. J. 2008. Rates of fluvial bedrock incision within an actively uplifting orogen: Central Karakoram Mountains, northern Pakistan. Geomorphology, 97: 274–286
Shahzad F, Gloaguen R. 2011a. TecDEM: A MATLAB based toolbox for tectonic geomorphology, Part 1: Drainage network preprocessing and stream profile analysis. Comput Geoscis, 37: 250–260
Shahzad F, Gloaguen R. 2011b. TecDEM: A MATLAB based toolbox for tectonic geomorphology, Part 2: Surface dynamics and basin analysis. Comput Geoscis, 37: 261–271
Shen Y C. 1956. geomorphology of the hanshui valley. Acta Geogr Sin, 23: 296–323
Shi X, Yang Z, Dong Y, Qu H, Zhou B, Cheng B. 2020. Geomorphic indices and longitudinal profile of the Daba Shan, northeastern Sichuan Basin: Evidence for the late Cenozoic eastward growth of the Tibetan Plateau. Geomorphology, 353: 107031
Shugar D H, Clague J J, Best J L, Schoof C, Willis M J, Copland L, Roe G H. 2017. River piracy and drainage basin reorganization led by climatedriven glacier retreat. Nat Geosci, 10: 370–375
Singh A, Thomsen K J, Sinha R, Buylaert J P, Carter A, Mark D F, Mason P J, Densmore A L, Murray A S, Jain M, Paul D, Gupta S. 2017. Counter-intuitive influence of Himalayan river morphodynamics on Indus Civilisation urban settlements. Nat Commun, 8: 1617
Strahler A N. 1952. Hypsometric (area-altitude) analysis of erosional topography. Geol Soc Am Bull, 63: 1117–1141
Suhail H A, Yang R, Chen H, Rao G. 2020. The impact of river capture on the landscape development of the Dadu River drainage basin, eastern Tibetan plateau. J Asian Earth Sci, 198: 104377
Sun X, Lu H, Wang S, Xu X, Zeng Q, Lu X, Lu C, Zhang W, Zhang X, Dennell R. 2018. Hominin distribution in glacial-interglacial environmental changes in the Qinling Mountains range, central China. Quat Sci Rev, 198: 37–55
Sun X, Lu H, Wang S, Yi L, Li Y, Bahain J J, Voinchet P, Hu X, Zeng L, Zhang W, Zhuo H. 2017. Early human settlements in the southern Qinling Mountains, central China. Quat Sci Rev, 164: 168–186
Teng Z H, Wang X H. 1996. Studies of the tectonic uplift at the Cenozoic era and the regionally environmental effects in the Qinling orogenic belt (in Chinese). Geol Shaanxi, 14: 33–42
Turzewski M D, Huntington K W, Licht A, Lang K A. 2020. Provenance and erosional impact of Quaternary megafloods through the Yarlung- Tsangpo Gorge from zircon U-Pb geochronology of flood deposits, eastern Himalaya. Earth Planet Sci Lett, 535: 116113
Wang S J, Lu H Y. 2014. Current Perspectives on Paleolithic Archaeology in the Upper Hanjiang River Valley, Central China (in Chinese). Acta Anthropol Sin, 33: 315–328
Wang S J, Lu H Y. 2016. Taphonomic and paleoenvironmental issues of the Pleistocene loessic Paleolithic sites in the Qinling Mountains, central China. Sci China Earth Sci, 59: 1519–1528
Whipple K X, Forte A M, DiBiase R A, Gasparini N M, Ouimet W B. 2017. Timescales of landscape response to divide migration and drainage capture: Implications for the role of divide mobility in landscape evolution. J Geophys Res-Earth Surf, 122: 248–273
Whipple K X. 2004. Bedrock rivers and the geomorphology of active orogens. Annu Rev Earth Planet Sci, 32: 151–185
Whittaker A C. 2012. How do landscapes record tectonics and climate? Lithosphere, 4: 160–164
Wiedenbeck M, Allé P, Corfu F, Griffin W L, Meier M, Oberli F, Quadt A V, Roddick J C, Spiegel W. 1995. Three natural zircon standards for UTh- Pb, Lu-Hf trace element and REE analysis. Geostand Geoanal, 19: 1–23
Willett S D, Slingerland R, Hovius N. 2001. Uplift, shortening, and steady state topography in active mountain belts. Am J Sci, 301: 455–485
Willett S D, McCoy S W, Perron J T, Goren L, Chen C Y. 2014. Dynamic reorganization of river basins. Science, 343: 1248765
Wobus C, Whipple K X, Kirby E, Snyder N, Johnson J, Spyropolou K, Crosby B, Sheehan D. 2006. Tectonics from topography: Procedures, promise, and pitfalls. Geol Soc Am Bull, Special Paper, 398: 55–74
Wu F H, Liu S W, Li Q G, Wang Zongqi, Su Li, Yang Kai, Zhang Fan, Yan Quanren and Yan Zhen. 2009. Zircon U-Pb Geochronology and Geological Significance of Guangtoushan Granitoids from Western Qinling, Central China (in Chinese). Acta Sci Nat Univ Pekinensis, 45: 811–818
Wu M L, Guo Y F, Li X J. 2009. Zircon LA-ICP-MS U-Pb Dating of the Guandiping Diorite Pluton from Mianxian, South Qinling, Central China (in Chinese). Northwestern Geol, 42: 73–78
Xia L, Xia Z, Ma Z, Xu X, Li X. 2009. Petrogenesis of volcanic rocks from Xixiang Group in middle part of South Qinling Mountains. Northwestern Geol, 42: 1–37
Xu X, Chen J, Li X, Ma Z, Wang H, Li P, Li T. 2009. Geochemical constrains on the petrogenesis and tectonic setting discrimination of volcanic rocks from the Baimianxia and the Sanwan Formations. Acta Geol Sin, 83: 1703–1718
Yan Q R, Andrew D H, Wang Z Q, Yan Z, Peter A D, Wang T, Liu D Y, Song B, Jiang C Fs. 2004. Geochemistry and tectonic setting of the Bikou volcanic terrane on the northern margin of the Yangtze plate (in Chinese). Acta Petrol ET Mineral, 23: 1–11
Yang C H, Wei C J, Zhang S G, Li H M, Wan Y S, Li R S. 1999. U-Pb Zircon dating of granulite facies rocks from the Foping area in the Southern Qinling Mountains (in Chinese). Geol Rev, 45: 173–179
Yang R, Willett S D, Goren L. 2015. In situ low-relief landscape formation as a result of river network disruption. Nature, 520: 526–529
Yang X. 2016. My humble opinion on Wudu earthquake in early Han Dynasty and the changes of water system in the upper reaches of Han River-a discussion with Mr. Zhou Hongwei (in Chinese). Hist Geog, (02): 229–239
Yanites B J, Ehlers T A, Becker J K, Schnellmann M, Heuberger S. 2013. High magnitude and rapid incision from river capture: Rhine River, Switzerland. J Geophys Res-Earth Surf, 118: 1060–1084
Zhang B P. 2019. Ten major scientific issues concerning the study of China’s north-south transitional zone (in Chinese). Prog Geog, 38: 305–311
Zhang G W, Meng Q R, Yu Z P, Sun Y, Zhou D W, Guo A L. 1996. Orogenesis and dynamics of the Qinling Orogen. Sci China Ser D-Earth Sci, 39: 225–234
Zhang H, Lu H, Xu X, Liu X, Yang T, Stevens T, Bird A, Xu Z, Zhang T, Lei F, Feng H. 2016. Quantitative estimation of the contribution of dust sources to Chinese loess using detrital zircon U-Pb age patterns. J Geophys Res-Earth Surf, 121: 2085–2099
Zhang Y Q, Shi W, Li J H, Wang R R, Li H L, Dong S W. 2010. Formation Mechanism of the Dabashan Foreland Arc-Shaped Structural belt (in Chinese). Acta Geol Sin, 84: 1300–1315
Zhang Z, Daly J S, Li C, Tyrrell S, Sun X, Yan Y. 2017. Sedimentary provenance constraints on drainage evolution models for SE Tibet: Evidence from detrital K-feldspar. Geophys Res Lett, 44: 4064–4073
Zhang Z Q, Zhang G W, Fu G M, Tang S H, Song B. 1996. Geochronology of metamorphic strata in the Qinling Mountains and its tectonic implications. Sci China Ser D-Earth Sci, 39: 283–292
Zhang Z Q, Zhang G W, Tang S H, Wang J H. 2001. On the age of Metamorphic Rocks of the Yudongzi Group and the Archean Crystalline Basement of the Qinling Orogen (in Chinese). Acta Geol Sin, 75: 198–204
Zhao B Q, Zhou Y Z. 2013. Query on Wudu Earthquake in Early Han Dynasty and Water System Change in the Upper Reaches of Han River- Discussion with Mr,Zhou Hongwei(in Chinese). Hist Geog, (02): 349–357
Zhao F, Zhao W, Zuo Y, Li Z, Xue K. 2006. U-Pb geochronology of Neoproterozoic magmatic rocks in Hanzhong, southern Shaanxi, China. Geol Bull China, 25: 383–388
Zhao J, Zhou M. 2008. Neoproterozoic adakitic plutons in the northern margin of the Yangtze Block, China: Partial melting of a thickened lower crust and implications for secular crustal evolution. Lithos, 104: 231–248
Zhao J, Zhou M, Zheng J, Fang S. 2010. Neoproterozoic crustal growth and reworking of the Northwestern Yangtze Block: Constraints from the Xixiang dioritic intrusion, South China. Lithos, 120: 439–452
Zheng H, Clift P D, Wang P, Tada R, Jia J, He M, Jourdan F. 2013. Pre- Miocene birth of the Yangtze River. Proc Natl Acad Sci USA, 110: 7556–7561
Zheng Y F, Xiao W J, Zhao G. 2013. Introduction to tectonics of China. Gondwana Res, 23: 1189–1206
Zhou M, Yan D, Kennedy A K, Li Y, Din J. 2002. SHRIMP U-Pb zircon geochronological and geochemical evidence for Neoproterozoic arcmagmatism along the western margin ofthe Yangtze Block, South China. Earth Planet Sci Lett, 196: 51–67
Zhou H W. 2010. Wudu earthquake in early Han Dynasty and the changes of water system in the upper reaches of Han River (in Chinese). Historical Research, (04): 49–69
Zhu Z, Dennell R, Huang W, Wu Y, Qiu S, Yang S, Rao Z, Hou Y, Xie J, Han J, Ouyang T. 2018. Hominin occupation of the Chinese Loess Plateau since about 2.1 million years ago. Nature, 559: 608–612
Acknowledgements
We thank Jef Vandenberhe and Ronald Van Balen for their encouragement of this work. We also thank Yang Yu, Xun Yang, Linman Gao, and Qi Su for their fieldwork assistance. We extend our appreciation to the responsible editor and two anonymous reviewers for providing thoughtful insights and constructive suggestions. This work was supported by the National Natural Science Foundation of China (Grant Nos. 41971005, 41522101, 41901004), the Second Tibet Plateau Scientific Research (Grant No. 2019QZKK0205), and the Major Program of National Social Science Foundation of China (Grant No. 19ZDA225).
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Xie, W., Wang, X., Zhang, H. et al. Drainage evolution in intermontane basins at the Qinling-Daba Mountains. Sci. China Earth Sci. 64, 1949–1968 (2021). https://doi.org/10.1007/s11430-020-9820-y
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DOI: https://doi.org/10.1007/s11430-020-9820-y