The nature of stress state: numerical and laboratory experiments and some field observations-Reference-Cited by-同舟云学术

The nature of stress state: numerical and laboratory experiments and some field observations

Published:2015 Issue:1 Volume:409 Page:93-106
ISSN:0305-8719
Container-title:Geological Society, London, Special Publications
language:en
Short-container-title:Geological Society, London, Special Publications

Author:

Harper T. R.¹,Hagan J. T.²

Affiliation:

1. Geosphere Ltd., Netherton Farm, Sheepwash, Beaworthy, Devon EX21 5PL, UK

2. 47, Heathfield South, Twickenham, Middlesex TW2 7SR UK

Abstract

AbstractSimulations of the stress state in a region of discontinuously fractured rock revealed a strongly heterogeneous, self-organized stress distribution displaying internally balanced strains and corresponding energy storage. The explicit simulations follow a sequence which may be inferred to be irreversible and strongly dependent on interaction between fractures, implying a time-dependency. The state of the simulated reservoir displays a sensitivity characteristic of marginal stability. These numerical observations are compared with new and previous laboratory and field experiments spanning a wide range of size, stress magnitude and stress difference. The characteristics of the state of the simulated reservoir, laboratory samples and field behaviour are found to be consistent with the numerical predictions. A stress memory is evident. This supports previous conclusions that the concept of stress state as uniform, constant and resulting from averaged values of stresses or displacements, presently applied at remote and artificial boundaries, is grossly oversimplified and flawed.

Publisher

Geological Society of London

Subject

Geology,Ocean Engineering,Water Science and Technology

Reference50 articles.

1. Amadei B. & Stephansson O. 1997. Rock Stress and its Measurement. Chapman & Hall, London.

2. Brady B. H. G. , Lemos J. V. & Cundall P. A. 1986. Stress measurement schemes for jointed and fractured rock. In: Stephansson O. (ed.) Rock Stress and Rock Stress Measurements. Centek, Luleå, Sweden, 167–176.

3. Brereton R. & Muller B. 1991. European stress: contributions from borehole breakouts. In: Whitmarsh R. B. , Bott M. H. P. , Fairhead J. D. & Kusznir N. J. (eds) Tectonic Stress in the Lithosphere. The Royal Society, London.

4. Brujic J. , Wang P. , Song C. , Johnson D. L. , Sindt O. & Makse H. A. 2005. Granular dynamics in compaction and stress relaxation. Physical Review Letters, PTL 95, 128001-1-128001-4.

5. Couples G. D. 2013. Geomechanical impacts on flow in fractured reservoirs. In: Spence G. H. , Redfern J. , Aguilera R. , Bevan T. G. , Cosgrove J. W. , Couples G. D. & Daniel J.-M. (eds) Advances in the Study of Fractured Reservoirs. Geological Society, London, Special Publications, 374.

Cited by 3 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Dependence of stress state on the histories of burial, erosion, mechanical properties, pore pressure and faulting;International Journal of Rock Mechanics and Mining Sciences;2020-12

2. Strain superposition and fault stability during sequential hydraulic fracturing;Geological Society, London, Special Publications;2017

3. Towards an improved understanding of the mechanical properties and rheology of the lithosphere: an introductory article to ‘Rock Deformation from Field, Experiments and Theory: A Volume in Honour of Ernie Rutter’;Geological Society, London, Special Publications;2015