Energy Exploration & Exploitation (Jan 2023)

Pore characteristics of black shale in Da’anzhai member of Jurassic in central Sichuan Basin, China

  • Shengyang Xie,
  • Xiyan Yang,
  • Xingzhi Wang,
  • Fei Huo,
  • Zhongliang Ma,
  • Caiming Zhang,
  • Mengyao Jia,
  • Jiahao Kang,
  • Qinfan Yi,
  • Zisang Huang,
  • Yang Li,
  • Rong Yang

DOI
https://doi.org/10.1177/01445987221115815
Journal volume & issue
Vol. 41

Abstract

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The lacustrine shale in the Da’anzhai member of Jurassic in the central Sichuan Basin is a key exploration target for shale oil and gas resources in China in the future. This paper presents a detailed study of shale rock types and component characteristics, shale pore types and structural characteristics, and shale pore evolution characteristics under thermal simulation conditions through experimental analyses such as rock thin section and field emission scanning electron microscopy (FE-SEM) observation, conventional physical property test, X-ray diffraction (XRD) analysis, TOC test, liquid nitrogen adsorption (LNA) test, and thermal simulation (pore) experiment. The results show that minerals in the Da’anzhai shale are mainly clay minerals, quartz, and calcite, with a small amount of feldspar, dolomite, and pyrite. In the shale oil reservoirs, there are dominantly inorganic pores (e.g. clay intergranular pores), and relatively few organic pores. The specific surface area ranges from 1.064 m 2 /g to 9.227 m 2 /g, with an average of 4.949 m 2 /g. The pore volume is 0.003–0.016 cm 3 /g, with an average of 0.010 cm 3 /g. Mesopores contribute the most to the total pore volume and total specific surface area. With the increase of thermal simulation temperature, the degree of shale thermal evolution increases, and the shale porosity increases, predominantly, owing to the contribution of organic pores. It is concluded that inorganic pores, especially clay intergranular pores, are the dominant pore type in the Da’anzhai shale oil reservoirs, and the evolution degree, burial time and depth of organic matter can obviously improve the organic pores.