Thermo-mechanical characterization of shale using nanoindentation
Abstract Shale can be a potential buffer for high-level radioactive nuclear wastes. To be an effective buffer while subject to waste heat, shale's mechanical response at elevated temperature must be known. Many researchers have experimentally characterized the mechanical behavior of various sha...
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doaj-9755ce1850f84ce184b5b9370f13c62d2021-09-26T11:27:33ZengNature Publishing GroupScientific Reports2045-23222021-09-0111111210.1038/s41598-021-98251-xThermo-mechanical characterization of shale using nanoindentationYanbo Wang0Debora Lyn Porter1Steven E. Naleway2Pania Newell3Integrated Multi-Physics Lab, Department of Mechanical Engineering, The University of UtahBioinspired Science and Engineering, Department of Mechanical Engineering, the University of UtahBioinspired Science and Engineering, Department of Mechanical Engineering, the University of UtahIntegrated Multi-Physics Lab, Department of Mechanical Engineering, The University of UtahAbstract Shale can be a potential buffer for high-level radioactive nuclear wastes. To be an effective buffer while subject to waste heat, shale's mechanical response at elevated temperature must be known. Many researchers have experimentally characterized the mechanical behavior of various shales at different length scales in adiabatic conditions. However, its mechanical performance at elevated temperatures at the nano-scale remains unknown. To investigate the temperature dependency of nanomechanical properties of shale, we conducted both experimental and numerical studies. In this study, we measured mechanical and fracture properties of shale, such as hardness, elastic modulus, anisotropy, and fracture toughness from 25 °C up to 300 °C at different bedding planes. Statistical analysis of the results suggests that hardness and fracture toughness significantly increased at temperatures from 100 to 300 °C; while, temperature does not have a significant impact on elastic modulus. Data also shows that the bedding plane orientations have a substantial impact on both mechanical and fracture properties of shale at the nano-scale leading to distinct anisotropic behavior at elevated temperature below 100 °C. Additionally, we numerically investigated the mechanical performance of the shale samples at room temperature to gain an insight into its mechanical response through the thickness. Numerical results were validated against the experimental results, confirming the simulation can be used to predict shale deformation at the nano-scale or potentially be used in multi-scale simulations.https://doi.org/10.1038/s41598-021-98251-x |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Yanbo Wang Debora Lyn Porter Steven E. Naleway Pania Newell |
spellingShingle |
Yanbo Wang Debora Lyn Porter Steven E. Naleway Pania Newell Thermo-mechanical characterization of shale using nanoindentation Scientific Reports |
author_facet |
Yanbo Wang Debora Lyn Porter Steven E. Naleway Pania Newell |
author_sort |
Yanbo Wang |
title |
Thermo-mechanical characterization of shale using nanoindentation |
title_short |
Thermo-mechanical characterization of shale using nanoindentation |
title_full |
Thermo-mechanical characterization of shale using nanoindentation |
title_fullStr |
Thermo-mechanical characterization of shale using nanoindentation |
title_full_unstemmed |
Thermo-mechanical characterization of shale using nanoindentation |
title_sort |
thermo-mechanical characterization of shale using nanoindentation |
publisher |
Nature Publishing Group |
series |
Scientific Reports |
issn |
2045-2322 |
publishDate |
2021-09-01 |
description |
Abstract Shale can be a potential buffer for high-level radioactive nuclear wastes. To be an effective buffer while subject to waste heat, shale's mechanical response at elevated temperature must be known. Many researchers have experimentally characterized the mechanical behavior of various shales at different length scales in adiabatic conditions. However, its mechanical performance at elevated temperatures at the nano-scale remains unknown. To investigate the temperature dependency of nanomechanical properties of shale, we conducted both experimental and numerical studies. In this study, we measured mechanical and fracture properties of shale, such as hardness, elastic modulus, anisotropy, and fracture toughness from 25 °C up to 300 °C at different bedding planes. Statistical analysis of the results suggests that hardness and fracture toughness significantly increased at temperatures from 100 to 300 °C; while, temperature does not have a significant impact on elastic modulus. Data also shows that the bedding plane orientations have a substantial impact on both mechanical and fracture properties of shale at the nano-scale leading to distinct anisotropic behavior at elevated temperature below 100 °C. Additionally, we numerically investigated the mechanical performance of the shale samples at room temperature to gain an insight into its mechanical response through the thickness. Numerical results were validated against the experimental results, confirming the simulation can be used to predict shale deformation at the nano-scale or potentially be used in multi-scale simulations. |
url |
https://doi.org/10.1038/s41598-021-98251-x |
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