Multi-scale evaluation of mechanical properties of the Bakken shale

Multi-scale evaluation of mechanical properties of the Bakken shale

Understanding mechanical properties of shale has been the topic of research in the past decade due to its importance in hydraulic fracturing and rock physics modeling. Since shales are highly heterogeneous in constituent components, detailed understanding of mechanical properties in a multi-scale (n...

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Bibliographic Details
Published in:Journal of materials science 2019-02, Vol.54 (3), p.2133-2151
Main Authors: Li, Chunxiao, Ostadhassan, Mehdi, Abarghani, Arash, Fogden, Andrew, Kong, Lingyun
Format: Article
Language:eng
Subjects:
Algorithms
Anisotropy
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Composites
Crystallography and Scattering Methods
Effective medium theory
Geochemistry
Hardness
Hydraulic fracturing
Identification methods
Mapping
Materials Science
Mechanical properties
Mineralogy
Modulus of elasticity
Multiscale analysis
Multivariate analysis
Nanoindentation
Oil shale
Oil wells
Organic carbon
Plugs
Polymer Sciences
Pyrolysis
Solid Mechanics
Statistical analysis
Statistical methods
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Summary:Understanding mechanical properties of shale has been the topic of research in the past decade due to its importance in hydraulic fracturing and rock physics modeling. Since shales are highly heterogeneous in constituent components, detailed understanding of mechanical properties in a multi-scale (nano, micro, macro and field) is vital and can present various results. In this study, we used a combination of analytical methods including high-resolution mineral mapping (MAPS), programmed pyrolysis and nanoindentation to identify mineralogy, geochemistry and nanomechanical characteristics of the Bakken shales in Williston Basin, North Dakota. Nanoindentation measurements were done both parallel and perpendicular to the bedding plane to examine mechanical anisotropy. Data were analyzed via multivariate statistical deconvolution technique (maximum likelihood approach and expectation–maximization algorithms) to reveal different mechanical phases, considering their Young’s modulus and hardness. Based on recognized components in the samples and measured values, Young’s modulus was upscaled through effective medium theory. Results showed that total organic carbon (TOC) content has a decreasing effect on Young’s modulus values. It was found that mechanical anisotropy increases with an increasing TOC content. Finally, upscaled Young’s modulus results were compared with reported measurements on core plugs which was found in a reasonable agreement.
ISSN:0022-2461
1573-4803