Abstract

Abstract By performing scanning electron microscopy, microscopic observations, whole-rock X-ray diffraction analysis, organic geochemistry analysis, and elemental analysis on drill core specimens and thin sections, in this study, we classified the shale types of the Wufeng Formation-Member 1 of the Longmaxi Formation in western Hubei, southern China, and explored the development characteristics and formation environments of the different shale types. The results show that (1) the shales of the Wufeng Formation-Member 1 of the Longmaxi Formation are composed of three types of shale: siliceous shale, mixed clay-siliceous shale, and clay shale. The siliceous shale is a type of shale unique to deep-water environments; clay shale is the main type of shale formed in shallow-water environments; and mixed clay-siliceous shale falls between the two. (2) The changes in shale type are characterized by multiple depositional cycles in the vertical direction with strong heterogeneity and an obvious tripartite character, and the siliceous shales gradually thicken as they laterally extend northwestward, with their last depositional cycle gradually ending at a later time. (3) The Late Ordovician-Early Silurian paleoenvironment can be divided into six evolutionary stages (A, B, C, D, E, and F) from early to late. In particular, the sea level was relatively lower in stages A and F when the bottom water was mainly oxygen rich with higher terrigenous inputs and a lower paleoproductivity, which led to the formation of clay shales poor in organic matter but rich in terrigenous quartz clasts. The sea level was higher in stages B, C, and D when the bottom water was anoxic with lower terrigenous inputs and a higher paleoproductivity, which led to the formation of siliceous shales rich in organic matter and biogenic silica. The total organic carbon (TOC) contents of siliceous shales decrease in the order of stage C > stage D > stage B, which is mainly attributed to the different degrees of water restriction in the three stages and the consequently different paleoproductivities. Stage E corresponds to the mixed clay-siliceous shales, the depositional environment of which is between those of the siliceous shales and the clay shales, thereby resulting in the mineral composition and TOC content of the mixed clay-siliceous shales being between those of the other two shale types.

Highlights

  • Earlier studies have suggested that shale formed in a specific environment is homogeneous without obvious structures, but shales with heterogeneous characteristics have been widely reported with the advancement of finegrained sedimentology [1,2,3], and it has been accepted that shale is composed of different types of rocks that areThis work is licensed under the Creative Commons Attribution 4.01596 Junjun Shen et al.rich in organic matter [4]

  • The sea level was higher in stages B, C, and D when the bottom water was anoxic with lower terrigenous inputs and a higher paleoproductivity, which led to the formation of siliceous shales rich in organic matter and biogenic silica

  • Earlier studies have discovered that the differences in the mineral compositions, sedimentary structures, organic matter contents, and paleontological types and abundances of different types of rocks are the result of the combined action of the basin structure, water environment, terrigenous supply, climate change, and sea-level rise and fall during shale deposition [9,10,11]

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Summary

Introduction

Earlier studies have suggested that shale formed in a specific environment is homogeneous without obvious structures, but shales with heterogeneous characteristics have been widely reported with the advancement of finegrained sedimentology [1,2,3], and it has been accepted that shale is composed of different types of rocks that are. Based on the classification results, we clarified the development characteristics and temporal-spatial patterns of the different shale types, explored the formation environments of different shale types in terms of sea level variations, terrestrial inputs, redox conditions, paleoproductivity, and water restriction and established depositional evolution models

Regional geologic background
Sampling and analytical methods
Shale classification scheme
Siliceous shales
Clay-siliceous mixed shales
Clay shales
Vertical evolution characteristics
Lateral distribution characteristics
Ancient sea-level changes
Paleoredox conditions
Terrigenous input
Degree of water restriction
Paleoproductivity
Depositional evolution models for the different shale types
Conclusion

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