Fracture development in high pressure experiment of shale in Texas, USA

Abstract

Organic-rich shale has been generally considered as a source rock in hydrocarbon reservoir. With the advancement of horizontal drilling and hydraulic fracturing techniques, recently shale formation can be directly extracted for hydrocarbon. Despite the extensive studies of shale characteristics, there is little information about mechanical behavior and fracture system of shale during hydraulic fracturing process. This study thus aims to simulate the high pressure and high temperature conditions of hydraulic fracturing process and investigate microstructural and mechanical changes of the Barnett Shale from Texas, USA. The multi-anvil press D-DIA apparatus equipped with synchrotron X-ray diffraction (SYN-XRD) technique is used to compress shale to 240 MPa while simultaneously heated to 100 ºc, and monitor compositional various. Moreover, synchrotron X-ray tomographic microscopy (SYN-MCT) is further used to investigate threedimensional (3D) fractures, pores, and organic material (kerogen) of compressed shale. SYN-XRD results show that the sample is mainly composed of quartz (~35%), illite-mica (~28%), and illitesmectite (~25%). Minor minerals include kaolinite (~3%) and pyrite (~9%). Upon compressing sample, the volumes of illite-smectite decrease due to dehydration. Differential stresses of clay minerals and quartz are determined from diffraction patterns, suggesting illite-smectite is the least stiff mineral due to the highest differential stress (~2-3 GPa) whereas quartz is the most stiff one. In addition, SYN-MCT results provide the 3D morphology and distribution of pore, fracture, and kerogen. Pores (~3 vol.%) are mostly rounded and scattered in the sample while kerogen is (~15 vol.%) mostly elongated and aligned parallel with pores. Upon compression, fractures start to develop and become prominent (1.27 vol.%) while unloading, propagating intersect the principal stress direction at the average angle of 26º. Permeability is calculated from these fractures, ranging from 6.4 to 9.3 mD.