Paleoenvironment Evolutionary Characteristics of Niutitang Shale in Western Hubei, Middle Yangtze, China

Lulu Xu; Saipeng Huang; Zaoxue Liu; Yanlin Zhang; Yaru Wen; Xianghui Zhou; Wei Chen; Zhijun Ren; Jianhang Wen

doi:10.1021/acsomega.2c01726

Paleoenvironment Evolutionary Characteristics of Niutitang Shale in Western Hubei, Middle Yangtze, China

ACS Omega. 2022 Jul 11;7(28):24365-24383. doi: 10.1021/acsomega.2c01726. eCollection 2022 Jul 19.

Authors

Lulu Xu^{1

2}, Saipeng Huang^{3

4}, Zaoxue Liu¹, Yanlin Zhang¹, Yaru Wen¹, Xianghui Zhou¹, Wei Chen¹, Zhijun Ren¹, Jianhang Wen¹

Affiliations

¹ Hubei Geological Survey, Wuhan, Hubei 430034, China.
² Hubei Research Center of Geological Exploration and Engineering Technology, Wuhan, Hubei 430034, China.
³ Key Laboratory of Continental Shale Accumulation and Development of Ministry of Education, Northeast Petroleum University, Daqing 163318, China.
⁴ Departament de Mineralogia, Petrologia i Geologia Aplicada, Facultat de Ciències de la Terra, Universitat de Barcelona (UB), c/ Martí i Franquès s/n, Barcelona 08028, Spain.

Abstract

The black shale developed in the first section of the Niutitang formation (ϵ₁ n ¹) is one of the most important shale gas reservoirs in western Hubei, and its geological characteristics have been sufficiently studied by many predecessors. However, there are still three aspects that need further research: the origin of silicon, the discrimination of the euxinic sulfuretted and the anoxic ferruginous conditions, and the main controlling factors of organic matter enrichment. Based on geochemical data from well ZD1 located in the city of Yichang in western Hubei, first, the geochemical characteristics of ϵ₁ n ¹ are analyzed, then the provenance, depositional site, and paleoenvironment evolution are discussed, and finally, the main controlling factor of organic matter enrichment is revealed. The results show that ϵ₁ n ¹ can be divided into two units, organic-rich shales (ORS) and organic-lean shales (OLS), which have average total organic carbon contents of 4.21 and 0.84%, respectively. Additionally, the ORS is characterized by high contents of SiO₂, U, V, Ni, Zn, and Cu and left-inclining types of rare earth element distribution curves. ϵ₁ n ¹ is located in a passive continental margin with a material source mainly from mixed felsic and mafic rocks. Compared with the OLS, the content of biological quartz is much greater, and the terrigenous input is less in the ORS. The paleoclimate is cold and humid with low salinity in the ORS, whereas it is hot and dry with high salinity in the OLS. ϵ₁ n ¹ is deposited in a semistagnant basin, and the ORS shows a relatively lower stagnant degree with euxinic to anoxic conditions and moderate to high paleoproductivity, while the OLS shows a high stagnant degree with suboxic to oxic conditions and lower paleoproductivity. The redox conditions are the main controlling factors affecting organic matter enrichment. The environmental evolution model with three stages shows that there is a good causal relationship between redox conditions, paleoproductivity, and sea level fluctuation. The black carbonaceous siliceous in the lower part of the ORS with a thickness of approximately 40 m is the most favorable layer, which will provide a theoretical basis for further shale gas exploration of ϵ₁ n ¹ in the western Hubei.