Abstract
As the last part of the Hercynian cycle in the Yangtze region, the Dongwu Movement included the eruption of the Emeishan large igneous province (ELIP) and was an essential event between the Guadalupian and Lo**ian, which had significant implications for the paleo-oceanic environment and paleoclimate of the area. To study the changes in the sedimentary environment in the Guadalupian and Lo**ian, the Zhenba section was selected, and its trace elements and rare earth elements (REEs) were analyzed. From analysis of the trace elements and REEs in the Guadalupian, the limestone samples had prominent typical shallow-water seawater deposition characteristics and were less affected by terrigenous detritus, which was in an arid oxidation environment; Sr/Cu ranged from 4 to 1381, the Rb/Sr value was low, δCe < 1, Ceanom < −0.1, Er/Nd ranged from 0.1 to 0.27, and Y/Ho ranged from 44 to 72. However, in the Lo**ian, the limestone samples were more affected by terrigenous detritus, which was in a humid climate with a weak oxidation‒reduction environment; the Sr/Cu ranged from 1 to 656, the Rb/Sr value was high, δCe ≅ 1, Ceanom ≥ −0.1, Er/Nd < 0.1, and Y/Ho ranged from 26 to 44. The geochemical diagrams of TiO2‒Al2O3, Al2O3‒REE, La‒Th‒Sc, Th‒Co‒Zr/10, Th‒Sc‒Zr/10 and 87Sr/86Sr of a sample indicated that the terrigenous detritus of the sample mainly came from the South Qinling active continental margin, rather than the weathering of Emeishan basalt. Acid bentonite came from the Paleo-Tethys island arc or the island arc formed by the subduction of the South China Plate beneath the North China Plate, rather than the ELIP. This evidence supported the view that the North China Plate potentially collided with the South China Plate in middle to late Wujia**.
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Acknowledgements
We are grateful to the China Geological Survey for its financial support. I am grateful to Dr. Gao C. for their supports in the petrographic section. Constructive suggestions from three anonymous reviewers are acknowledged with thanks.
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This study was supported by the China Geological Survey [number: DD20221661].
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YY wrote the main manuscript text. CM funded the paper and proposed revisions. ZG, QW, XW put forward different opinions for the article. BZ and PR provided technical support for the paper.
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Yao, S., Mou, C., Zhou, G. et al. Geochemistry of the Guadalupian—Lo**ian carbonate rocks from the NE Sichuan Basin, China: implications for paleo-oceanic environment and provenance. Carbonates Evaporites 39, 29 (2024). https://doi.org/10.1007/s13146-024-00934-9
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DOI: https://doi.org/10.1007/s13146-024-00934-9