Abstract
Petrographic, mineralogical, and geochemical analyses were conducted on Cenozoic sandstones from the Dunhua Basin, which located in Dunhua-mishan fault zone of northeast China, to investigate the provenance of the sediments, as well as the weathering intensity and tectonic setting of the source region. Petrographic data indicate that average quartz-feldspar-lithic (Q-F-L) proportions in the sandstones are Q = 68%, F = 16%, and L = 16%, the lithic fraction mainly contains volcanic clasts. The chemical index of alteration (CIA) varies from 59 to 69 (average 63), while the index of chemical variability (ICV) ranges from 0.68 to 0.91 (average 0.77), and the average Th/U ratio is 3.2. Chondrite-normalized REE distributions show LREEs enriched relative to HREEs, and a prominent negative Eu anomaly. These data indicating that the sandstones are compositionally immature and a weak degree of weathering in the source region. The petrographic and mineralogical characteristics, combine with Zr/Sc–Th/Sc, Hf–La/Th and Co/Th–La/Sc discrimination diagrams reveal that these sandstones are derived from the surrounding felsic volcanic and intrusive rocks of Late Triassic-Early Jurassic, which exposed to the southeast or northwest of the basin. Multidimensional tectonic discrimination diagrams, including geochemical data and Dickinson triangular charts, indicate that the sandstones were derived from recycled orogenic in an active continental margin setting.
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REFERENCES
C. J. Allegre and J. F. Minster, “Quantitative models of trace element behavior in magmatic processes,” Earth Planet. Sci. Lett. 38 (1), 1–25 (1978).
J. S. Armstrong-Altrin, R. Nagarajan, Y. I. Lee, et al., “Geochemistry of sands along the San Nicolas and San Carlos beaches, Gulf of California, Mexico: implications for provenance and tectonic setting,” Turk. J. Earth Sci 23, 533–55 (2014).
J. S. Armstrong-Altrin, M. L. Machain-Castillo, L. Rosales-Hoz, et al., “Provenance and depositional history of continental slope sediments in the southwestern Gulf of Mexico unraveled by geochemistry analysis,” Cont. Shelf Res 95, 15–26 (2015).
D. K. Asedu, S. Suzuki, K. Nogami, et al., “Geochemistry of Lower Cretaceous sediments, inner zone of Southwest Japan: constraints on provenance and tectonic environment,” Geochem. J. 34, 155–173 (2000).
Y. Bai, Z. Liu, P. Sun, et al., “Rare earth and major element geochemistry of Eocene fine-grained sediments in oil shale- and coal-bearing layers of the Meihe Basin, Northeast China,” J. Asian Earth Sci 97, 89–101 (2015).
M. R. Bhatia, “Plate tectonics and geochemical composition of sandstone,” J. Geol. 91 (6), 611–627 (1983).
M. R. Bhatia, “Rare earth element geochemistry of Australian Paleozoic greywackes and mudstones: provenance and tectonic control,” Sediment. Geol. 45, 97–113 (1985).
M. R. Bhatia and K. A. W. Crook, “Trace element characteristics of greywacke sand tectonic setting discrimination of sedimentary basins,” Contrib. Mineral. Petrol. 92, 181–193 (1986).
S. E. Calvert, R. M. Bustin, and E. D. Ingall, “Influence of water column anoxia and sediment supply on the burial and preservation of organic carbon in marine shales,” Geochim. Cosmochim. Acta 60, 1577–1593 (1996).
K. S. Camuti and P. T. McGuire, “Preparation of polished thin sections from poorly consolidated regolith and sediment materials,” Sediment. Geol. 28, 171–178 (1999).
K. Charles, A. H. M. Makenya, and M. Shukrani, “Geochemistry of fine-grained clastic sedimentary rocks of the Neoproterozoic Ikorongo Group, NE Tanzania: implications for provenance and source rock weathering,” Precambrian Res. 164, 201–213 (2008).
K. C. Condie, D. N. Phillip, and C. M. Conway, “Geochemical and detrital mode evidence for two sources of Early Proterozoic sedimentary rocks from Tonto Basin Super Group, Central Arizona,” Sediment. Geol. 77, 51–76 (1992).
R. Cox, D. R. Lowe, and R. L. Cullers, “The influence of sediment recycling and basement composition on evolution of mudrock chemistry in the Southwestern United States,” Geochim. Cosmochim. Acta 59, 2919–2940.
R. L. Cullers, T. R. Barrett, C. R. Carlson, et al., “Rare earth element and mineralogical changes in Holocene soil and stream sediment: a case study in the Wet Mountains, Colorado, USA,” Chem. Geol. 63, 275–297 (1987).
R. L. Cullers and V. N. Podkovyrov, “Geochemistry of the Mesoproterozoic Lakhanda shales in southeastern Yakutia. Russia: implications for mineralogical and provenance control, and recycling,” Precambrian Res. 104, 77–93 (2000).
W. R. Dickinson, “Interpreting detrital modes of graywacke and arkose,” J. Sediment. Petrol. 40, 695–707 (1970).
W. R. Dickinson and C. A. Suczek, “Plate tectonics and sandstone compositions,” AAPG 63, 189–194 (1979).
W. R. Dickinson, L. S. Beard, G. R. Brakenridge, et al., “Provenance of North American Phanerozoic Sandstones in relation to tectonic setting,” Geology 94 (2), 222–235 (1983).
W. R. Dickinson, “Interpreting provenance relations from detrital modes of sandstones,” Provenance of Arenites (D. Reidel Publ. Co, Dordrecht, 1985), pp. 333–361.
C. M. Fedo and H. W. Nesbtit, “Unravelling the effects of potassium metasomatism in sedimentary rocks and paleosoils with implications for paleoweathering conditions and provenance,” Geol. 23, 921–924 (1995).
P. A. Floyd and B. E. Leveridge, “Tectonic environment of the Devonian Gramscatho Basin, South Cornwall: framework mode and geochemical evidence from turbiditic sandstone,” J. Geol. Soc. London 144 (4), 531–542 (1987).
A. D. Hanson, B. D. Ritts, D. Zinniker, et al., “Upper Oligocene lacustrine source rocks and petroleum systems of the Northern Qaidam Basin, Northwest China,” AAPG Bull. 85, 601–620 (2001).
H. M. Holail and A. K. M. Moghazi, “Provenance, tectonic setting and geochemistry of greywackes and siltstones of the Late Precambrian Hammamat Group, Egypt,” Sediment. Geol. 116, 227–250 (1998).
H. M. Z. Hossain, B. P. Roser, and J. I. Kimura, “Petrography and whole-rock geochemistry of the Tertiary Sylhet Succession, Northeastern Bengal Basin, Bangladesh: provenance and source area weathering,” Sediment. Geol. 228, 171–183 (2010).
F. Hu, Cenozoic Tectonic and Sedimentary Evolution in Dunhua Basin and its Formation Mechanism (Jilin Univ, Changchun, 2013).
W. Hu, T. Zhang, H. Wang, et al., “A study on basin-forming mechanism and basin properties of Dunhua Basin,” Petrol. Geol. Eng. 22 (1), 25–33 (2008).
J. Huang, J. Ren, C. Jiang, et al., “An outline of the tectonic characteristics of China,” Acta Geol. Sin. 51 (2), 117–135 (1977).
R. V. Ingersoll, T. F. Fullard, R. L. Ford, et al., “The effect of grain size on detrital modes: a test of the Gazzi-Dickinson point-counting method,” J. Sediment. Petrol. 54, 103–116 (1984).
J. Jia, A. Bechtel, Z. Liu, et al., “Oil shale formation in the Upper Cretaceous Nenjiang Formation of the Songliao Basin (NE China): implications from organic and inorganic geochemical analyses,” Int. J. Coal Geol. 113, 11–26 (2013).
M. J. Johnsson, “The system controlling the composition of clastic sediments,” GSA Spec. Publ. 284, 1–19 (1993).
A. Lambeck, D. Huston, D. Maidment, et al., “Sedimentary geochemistry, geochronology and sequence stratigraphy as tools to typecast stratigraphic unit sand constrain basin evolution in the gold-mineralized Palaeoproterozoic Tanami Region, Northern Australia,” Precambrian Res. 166, 185–203 (2008).
Z. Li and C. Zhao, “Late Triassic magmatic activities in relation to plate tectonics of the eastern part of Jilin and Heilongjiang provinces, northeast China,” Bull. Chinese Acad. Geol. Sci 18, 21–32 (1988).
R. Liu, Z. Liu, P. Sun, et al., “Geochemistry of the Eocene Jijuntun Formation oil shale in the Fushun Basin, Northeast China: implications for source-area weathering, provenance and tectonic setting,” Chem. Der. Erde 75, 105–116 (2015).
J. Madhavaraju and Y. Lee, “Influence of Deccan volcanism in the sedimentary rocks of Late Maastrichtian–Danian age of Cauvery Basin, southeastern India: constraints from geochemistry,” Cur. Sci. India 98, 528–537 (2010).
T. McCann, “Sandstone composition and provenance of the Rotliegend of the NE German Basin,” Sediment. Geol. 116, 177–198 (1998).
S. M. McLennan, “Rare earth elements in sedimentary rocks: influence of provenance and sedimentary processes,” Rev. Mineral. Geochem. 21, 169–200 (1989).
S. M. McLennan, S. R. Taylor, M. T. McCulloch, et al., “Geochemical and Nd-Sr isotopic composition of deep-sea turbidites: crustal evolution and plate tectonic associations,” Geochim. Cosmochm. Acta 43, 375–388 (1990).
S. M. McLennan, S. Hemming, D. K. McDaniel, et al., “Geochemical approaches to sedimentation, provenance, and tectonics,” Geol. Soc. Am. Spec. Pap. 284, 21–40 (1993).
S. M. McLennan, S. R. Hemming, S. R. Taylor, et al., “Early Proterozoic crustal evolution: geochemical and Nd-Pb isotopic evidence from metasedimentary rocks, southwestern North America,” Geochim. Cosmochim. Acta 59, 1153–1177 (1995).
S. M. McLennan, “Relationships between the trace element composition of sedimentary rocks and upper continental crust,” Geochem. Geophys. Geosyst. 2, 10–21 (2001).
J. L. Mercier, M. Hou, P. Vergely, et al., “Structural and stratigraphical constraints on the kinematics history of the southern Tan-Lu Fault Zone during the Mesozoic Anhui Province, China,” Tectonophysics 439 (1), 33–66 (2007).
A. D. Miall, Principles of Sedimentary Basin Analysis (Springer-Verlag, 1990).
F. Migani, F. Borghesi, and E. Dinelli, “Geochemical characterization of surface sediments from the Northern Adriatic wetlands around the Poriver Delta. Part I: Bulk composition and relation to local background,” J. Geochem. Explor. 56, 72–88 (2015).
R. Nagarajan, J. S. Armstrong-Altrin, F. L. Kessler, et al., “Provenance and tectonic setting of Miocene siliciclastic sediments, Sibuti Formation, Northwestern Borneo,” Arab. J. Geo. Sci. 8, 8549–8565 (2015).
H. W. Nesbitt and G. M. Young, “Early Proterozoic climate and plate motion inferred from major element chemistry of lutites,” Nature 299, 715–717 (1982).
A. N. Odoma, N. G. Obaje, J. I. Omada, et al., “Mineralogical, chemical composition and distribution of rare earth elements in clay-rich sediments from southeastern Nigeria,” J. Afr. Earth Sci. 102, 50–60 (2015).
F. Pei, W. Xu, E. Meng, et al., “The start of Paleo-Pacific subduction: the evidence of the chronology and chemistry from early-middle Jurassic of the eastern part of Jilin and Heilongjiang provinces, northeast China,” Bull. Miner. Petrol. Geochem. 27 (Z1), 268 (2008).
M. JJ. Rahman, A. S. M. Sayem, and T. McCann, “Geochemistry and provenance of the Miocene sandstones of the Surma Group from the Sitapahar Anticline, southeastern Bengal Basin, Bangladesh,” J. Geol. Soc. India 83, 447–456 (2014).
J. Ren, “The Indosinian orogeny and its significance in the tectonic evolution of China,” Bull. Chinese Acad. Geol. Sci. 9, 31–44 (1984).
M. Roddaz, J. Viers, S. Brusset, et al., “Controls on weathering and provenance in the Amazonian foreland basin: insights from major and trace element geochemistry of Neogene Amazonian sediments,” Chem. Geol. 226, 31–65 (2006).
B. P. Roser and R. J. Korsch, “Determination of tectonic setting of sandstone–mudstone suites using SiO2 content and K2O/Na2O ratio,” J. Geol. 94, 635–650 (1986).
B. P. Roser and R. J. Korsch, “Provenance signatures of sandstone–mudstone suites determined using discriminant function analysis of major-element data,” Chem. Geol. 67 (1), 119–139 (1988).
D. J. K. Ross and R. M. Bustin, “Investigating the use of sedimentary geochemical proxies for paleoenvironment interpretation of thermally mature organic-rich strata: examples from the Devonian–Mississippian Shales, Western Canadian sedimentary basin,” Chem. Geol. 260, 1–19 (2009).
D. W. Schindler, R. E. Hecky, D. L. Findlay, et al., “Eutrophication of lake cannot be controlled by reducing nitrogen input: results of a 37-year whole-ecosystem experiment,” P. Natl. Acad. Sci 105, 11254–11258 (2008).
Y. Song, Z. Liu, Q. Meng, et al., “Petrography and geochemistry characteristics of the Lower Cretaceous Muling Formation from the Laoheishan Basin, Northeast China: implications for provenance and tectonic setting,” Mineral. Petrol. 16, 476–484 (2016).
X. Sun, S. Wang, Y. Wang, et al., “The structural feature and evolutionary series in the northern segment of the Tancheng-Lujiang fault zone,” Acta Petrol. Sin. 26 (1), 165–176 (2010).
S. R. Taylor and S. M. McLennan, The Continental Crust: Its Composition and Evolution. An Examination of the Geochemical Record Preserved in Sedimentary Rocks (Sci. Press, Beijing, 1985).
M. E. Tucker, Sedimentary Petrology: an Introduction to the Origin of Sedimentary Rocks (John Wiley & Sons, Malden, 2009).
S. P. Verma and J. S. Armstrong-Altrin, “Geochemical Discrimination of siliciclastic sediments from active and passive margin settings,” Sediment. Geol. 332, 1–12 (2016).
H. Wang, T. Zhang, C. Dai, et al., “Stratigraphic division and correlation of the Upper Jurassic–Pliocene in the Dunhua Basin,” Geol. China 35 (1), 40–53 (2008).
S. Wang, X. Sun, J. Du, et al., “Analysis of structural styles in the northern segment of the Tancheng–Lujiang Fault Zone,” Geol. Rev. 58 (3), 414–425 (2012).
Y. Wang and L. Dou, “Formation time and dynamic characteristics of the northern part of the Tan-Lu Fault Zone in East China,” Seism. Geol. 19 (2 P), 186–194 (1997).
T. Wan and H. Zhu, “The maximum sinistral strike-slip and its forming age of the Tancheng–Lujiang Fault Zone,” Geol. J. Univ. 2 (1), 14–27 (1996).
D. J. Wronkiewicz and K. C. Condie, “Geochemistry of Archean shales from the Wit-Watersrand Supergroup, South Africa: source-area weathering and provenance,” Geochim. Cosmochim. Acta 51, 2401–2416 (1987).
J. Wu, J. Luo, G. Yuan, et al., “Petroleum geologic conditions and exploration prospects of the Dunhua Basin,” J. Oil Gas Technol. 29 (5), 8–12 (2007).
W. Xu, F. Pei, F. Wang, et al., “Spatial–temporal relationships of Mesozoic volcanic rocks in NE China: constraints on tectonic overprinting and transformations between multiple tectonic regimes,” J. Asian Earth Sci 74, 167–193 (2013).
M. Yu, P. Wang, R. Wang, et al., “Source rock characteristics and oil-gas resource potential in the Dunhua Basin,” Geol. Sci. Technol. Inf. 27 (5), 65–70 (2008).
S. M. Zaid, “Provenance, diagenesis, tectonic setting and reservoir quality of sandstones of the Kareem Formation, Gulf of Suez, Egypt,” J. Afr. Earth Sci. 85, 31–52 (2013).
N. Zhang, C. M. Lin, and X. Zhang, “Petrographic and geochemical characteristics of the Paleogene sedimentary rocks from the North Jiangsu Basin, Eastern China: implication for provenance and tectonic setting,” Mineral Petrol. 108, 571–588 (2014).
Q. Zhang, L. Wang, G. Xie, et al., “Discussion on northward extension of the Tan-Lu Fault Zone and its tectonic regime transformation,” Geol. J. China Univ. 11 (40), 577–584 (2005).
Y. Zhang, Y. Sun, and X. Zhang, Geoscience Transect from Manzhouli-Suifenhe in China (Geol. Press, Beijing, 1998).
ACKNOWLEDGMENTS
We would also like to thank Dr. Jianpeng Wang of the University of Manchester for his help with the language in the paper.
Funding
The authors would like to thank the Opening Foundation of the Key Laboratory for Oil Shale and Paragenetic Energy Minerals, Jilin Province for their support. This study was supported financially by the China Geological Survey (Project no. 1211302108025-5-1).
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Hu, F., Liu, Z., Meng, Q. et al. Petrography and Geochemistry of Cenozoic Sandstones in the Dunhua Basin, Northeast China: Implications for Provenance, Source Weathering, and Tectonic Setting. Russ. J. of Pac. Geol. 14, 48–65 (2020). https://doi.org/10.1134/S1819714020010078
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DOI: https://doi.org/10.1134/S1819714020010078