Abstract
Brittleness and ductility of shale are closely related to shale gas exploration and production. How to predict brittleness and ductility of shale is one of the key issues in the study of shale gas preservation and hydraulic fracturing treatments. The magnitude of shale brittleness was often determined by brittle mineral content (for example, quartz and feldspars) in shale gas exploration. However, the shale brittleness is also controlled by burial depth. Shale brittle/ductile properties such as brittle, semi-brittle and ductile can mutually transform with burial depth variation. We established a work flow of determining the burial depth interval of brittle–ductile transition zone for a given shale. Two boundaries were employed to divide the burial depth interval of shale brittle/ductile properties. One is the bottom boundary of the brittle zone (BZ), and the other is the top boundary of the ductile zone (DZ). The brittle–ductile transition zone (BDTZ) is between them. The bottom boundary of BZ was determined by the over-consolidation ratio (OCR) threshold value combined with pre-consolidation stress which the shale experienced over geological time. The top boundary of DZ was determined based on the critical confining pressure of brittle–ductile transition. The OCR threshold value and the critical confining pressure were obtained from uniaxial strain and triaxial compression tests. The BZ, DZ and BDTZ of the Lower Silurian Longmaxi shale in some representative shale gas exploration wells in eastern Sichuan and western Hubei areas were determined according to the above work flow. The results show that the BZ varies with the maximum burial depth and the DZ varies with the density of the overlying rocks except for the critical confining pressure. Moreover, the BDTZ determined by the above work flow is probably the best burial depth interval for marine shale gas exploration and production in Southern China. Shale located in the BDTZ is semi-brittle and is not prone to be severely naturally fractured but likely to respond well to hydraulic fracturing. The depth interval of BDTZ determined by our work flow could be a valuable parameter of shale gas estimation in geology and engineering.
Highlights
The increasing significance of shale gas plays has led to the need for deeper understanding of shale behavior (Dewhurst et al 2015)
The results show that the brittle zone (BZ) varies with the maximum burial depth and the ductile zone (DZ) varies with the density of the overlying rocks except for the critical confining pressure
The bottom boundary of the brittle zone (BZ) was determined with the threshold value of the over-consolidation ratio (OCR) of shale combined with the pre-consolidation stress
Summary
The increasing significance of shale gas plays has led to the need for deeper understanding of shale behavior (Dewhurst et al 2015). In shale gas exploration and development, the brittle mineral content, the Young’s modulus and Poisson’s ratio are often employed to estimate shale brittleness. A parameter often used in soil mechanics to quantify the ductility or brittleness of clays is the over-consolidation ratio (OCR). It is defined as the ratio between the maximum effective vertical stress and the present effective vertical stress. The most often used method of employing the brittle mineral contents to estimate the magnitude of shale brittleness in shale gas exploration field is not always suitable if burial depth is ignored. The purpose is to roughly estimate shale gas preservation and hydraulic fracturing based on burial depth so as to lower geologic and engineering risks in exploration and production
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