Subcritical crack growth in rocks in an aqueous environment*

Yoshitaka Nara; Masafumi Takada; Toshifumi Igarashi; Naoki Hiroyoshi; Katsuhiko Kaneko

doi:10.1071/EG08102

RESEARCH ARTICLE

Previous Contents Vol 40(1)

Subcritical crack growth in rocks in an aqueous environment^*

Yoshitaka Nara ¹ ³ Masafumi Takada ² Toshifumi Igarashi ¹ Naoki Hiroyoshi ¹ Katsuhiko Kaneko ¹

+ Author Affiliations

- Author Affiliations

¹ Graduate School of Engineering, Hokkaido University, Kita 13 Nishi 8, Kita-ku, Sapporo, Hokkaido 060-8628, Japan.

² JGC Corporation, 2-3-1, Minato Mirai, Nishi-ku, Yokohama, Kanagawa 220-6001, Japan.

³ Corresponding author. Email: nara@geo-er.eng.hokudai.ac.jp

Exploration Geophysics 40(1) 163-171 https://doi.org/10.1071/EG08102
Submitted: 20 December 2007 Published: 27 February 2009

Abstract

Subcritical crack growth is one of the main causes of time-dependent fracturing in rock. In the present study, we investigated subcritical crack growth in rock in distilled water (pH = 5–7) and in an aqueous solution of sodium hydroxide (NaOHaq, pH = 12), comparing the results to those in air. We also investigated the effect of the pH in an aqueous environment. We used andesite and granite for all our tests. We determined the relationship between the crack velocity and the stress intensity factor using the double-torsion test under conditions of controlled temperature. We showed that crack velocities in water were higher than those in air, in agreement with other research results indicating that crack velocity increases in water. When we compared our results for NaOHaq with those for water, however, we found that the crack velocity at the same stress intensity factor did not change even though the pH of the surrounding environment was different. This result does not agree with the accepted understanding that hydroxide ions accelerate subcritical crack growth in rocks. We concluded that the pH at the crack tip influences subcritical crack growth, and not the bulk pH, which has little effect.

Key words: aqueous environment, double-torsion test, rock, subcritical crack growth, temperature.

Acknowledgment

We appreciate the support of Research Fellowship of the Japan Society for the Promotion of Science for Young Scientists.

References

Anderson, O. L., and Grew, P. C., 1977, Stress corrosion theory of crack propagation with applications to geophysics: Reviews of Geophysics and Space Physics 15, 77–104.
| Crossref | GoogleScholarGoogle Scholar | Kies J. A. , and Clark A. B. J. , 1969, Fracture propagation rates and times to fail following proof stress in bulk glass: in Platt, P.L. (ed.), Fracture 1969: Chapman and Hall, pp. 483–491.

Kodama N. , Fujii Y. , and Ishijima Y. , 2003, The effect of temperature on the mechanical properties of Inada granite and Shirahama sandstone: Kyoto, Japan: Proceedings of The First Kyoto International Symposium on Underground Environment – Role of Geo-technology to the Underground Environment, pp. 193–200.

Kudo Y. , Hashimoto K. , Sano O. , and Nakagawa K. , 1987, Relation between physical anisotropy and microstructures of granitic rock in Japan: Montreal, Canada: Proceedings of 6th International Congress on Rock Mechanics, pp. 429–432.

Michalske, T. A., and Freiman, S. W., 1982, A molecular interpretation of stress corrosion in silica: Nature 295, 511–512.
| Crossref | GoogleScholarGoogle Scholar | CAS | Nara Y. , 2004, Study of subcritical crack growth in rock: Ph.D. Thesis, Hokkaido University (in Japanese).

Nara, Y., and Kaneko, K., 2005, Study of subcritical crack growth in andesite using the Double Torsion test: International Journal of Rock Mechanics and Mining Sciences 42, 521–530.
| Crossref | GoogleScholarGoogle Scholar | Wiederhorn S. M. , 1978, Mechanisms of subcritical crack growth in glass: in Bradt, R.C., Hasselman, D.P.H. and Lange F.F. (eds.), Fracture Mechanics of Ceramics vol. 4: Chapman and Hall, pp. 549–580.

Wiederhorn, S. M., and Bolz, L. H., 1970, Stress corrosion and static fatigue of glass: Journal of the American Ceramic Society 53, 543–548.
| Crossref | GoogleScholarGoogle Scholar | CAS |

Wiederhorn, S. M., and Johnson, H., 1973, Effect of electrolyte pH on crack propagation in glass: Journal of the American Ceramic Society 56, 192–197.
| Crossref | GoogleScholarGoogle Scholar | CAS |

Williams, D. P., and Evans, A. G., 1973, A simple method for studying slow crack growth: Journal of Testing and Evaluation 1, 264–270.
| CAS |

^*Presented at the 19th ASEG Geophysical Conference & Exhibition, November 2007.