The effective stress can be defined as the stress, depending on the applied tension and pore pressure , which controls the strain or strength behaviour of soil and rock (or a generic porous body) for whatever pore pressure value or, in other terms, the stress which applied over a dry porous body (i.e. at ) provides the same strain or strength behaviour which is observed at ≠ 0. In the case of granular media it can be viewed as a force that keeps a collection of particles rigid. Usually this applies to sand, soil, or gravel, as well as every kind of rock and several other porous materials such as concrete, metal powders, biological tissues etc. The usefulness of an appropriate ESP formulation consists in allowing to assess the behaviour of a porous body for whatever pore pressure value on the basis of experiments involving dry samples (i.e. carried out at zero pore pressure).
History
Karl von Terzaghi first proposed the relationship for effective stress in 1925. For him, the term "effective" meant the calculated stress that was effective in moving soil, or causing displacements. It has been often interpreted as the average stress carried by the . Afterwards, different formulations have been proposed for the effective stress. Maurice Biot fully developed the three-dimensional soil consolidation theory, extending the one-dimensional model previously developed by Terzaghi to more general hypotheses and introducing the set of basic equations of Poroelasticity. Alec Skempton in his work in 1960, has carried out an extensive review of available formulations and experimental data in literature about effective stress valid in soil, concrete and rock, in order to reject some of these expressions, as well as clarify what expression was appropriate according to several work hypotheses, such as stress–strain or strength behaviour, saturated or nonsaturated media, rock/concrete or soil behaviour, etc.
In 1962, work by Jeremiah Jennings and John Burland examined the applicability of Terzaghi’s effective stress principle to partly saturated soils. Through a series of experiments undertaken at the University of the Witwatersrand, including oedometer and compression tests on various soil types, they showed that behaviours such as volume changes and shear strength in partly saturated soils do not align with predictions based on effective stress changes alone. Their findings showed that the structural changes due to pressure deficiencies behave differently from changes due to applied stress.
Description
Effective stress (σ') acting on a soil is calculated from two parameters, total stress (σ) and pore water pressure (u) according to:
Typically, for simple examples
Much like the concept of stress itself, the formula is a construct, for the easier visualization of forces acting on a soil mass, especially simple analysis models for slope stability, involving a slip plane. With these models, it is important to know the total weight of the soil above (including water), and the pore water pressure within the slip plane, assuming it is acting as a confined layer.[citation needed]
However, the formula becomes confusing when considering the true behaviour of the soil particles under different measurable conditions, since none of the parameters are actually independent actors on the particles.[citation needed]
Consider a grouping of round quartz sand grains, piled loosely, in a classic "cannonball" arrangement. As can be seen, there is a contact stress where the spheres actually touch. Pile on more spheres and the contact stresses increase, to the point of causing frictional instability (dynamic friction), and perhaps failure. The independent parameter affecting the contacts (both normal and shear) is the force of the spheres above. This can be calculated by using the overall average density of the spheres and the height of spheres above.[citation needed]
If we then have these spheres in a beaker and add some water, they will begin to float a little depending on their density (buoyancy). With natural soil materials, the effect can be significant, as anyone who has lifted a large rock out of a lake can attest. The contact stress on the spheres decreases as the beaker is filled to the top of the spheres, but then nothing changes if more water is added. Although the water pressure between the spheres (pore water pressure) is increasing, the effective stress remains the same, because the concept of "total stress" includes the weight of all the water above. This is where the equation can become confusing, and the effective stress can be calculated using the buoyant density of the spheres (soil), and the height of the soil above.[citation needed]
The concept of effective stress truly becomes interesting when dealing with non-hydrostatic pore water pressure. Under the conditions of a pore pressure gradient, the ground water flows, according to the permeability equation (Darcy's law). Using our spheres as a model, this is the same as injecting (or withdrawing) water between the spheres. If water is being injected, the seepage force acts to separate the spheres and reduces the effective stress. Thus, the soil mass becomes weaker. If water is being withdrawn, the spheres are forced together and the effective stress increases.
Two extremes of this effect are quicksand, where the groundwater gradient and seepage force act against gravity; and the "sandcastle effect", where the water drainage and capillary action act to strengthen the sand. As well, effective stress plays an important role in slope stability, and other geotechnical engineering and engineering geology problems, such as groundwater-related subsidence.
References
- Guerriero, V; Mazzoli, S. (2021). "Theory of Effective Stress in Soil and Rock and Implications for Fracturing Processes: A Review". Geosciences. 11 (3): 119. Bibcode:2021Geosc..11..119G. doi:10.3390/geosciences11030119.
- Terzaghi, Karl (1925). Erdbaumechanik auf Bodenphysikalischer Grundlage. F. Deuticke.
- Terzaghi, Karl (1936). "Relation Between Soil Mechanics and Foundation Engineering: Presidential Address". Proceedings, First International Conference on Soil Mechanics and Foundation Engineering, Boston. 3, 13–18.
- "Vertical stress in the ground". fbe.uwe.ac.uk. Archived from the original on June 18, 2006.
- Skempton, A. W. (1984-01-01), "Effective Stress in Soils, Concrete and Rocks", SELECTED PAPERS ON SOIL MECHANICS, Thomas Telford Publishing, pp. 106–118, doi:10.1680/sposm.02050.0014, ISBN 978-0-7277-3982-7, retrieved 2023-04-11
- Jennings, J. E. B.; Burland, J. B. (1962). "Limitations to the Use of Effective Stresses in Partly Saturated Soils". Géotechnique. 12 (2): 125–144. doi:10.1680/geot.1962.12.2.125. ISSN 0016-8505. Retrieved 12 April 2024 – via Institution of Civil Engineers Virtual Library.
- Escario, V.; Sáez, J. (1986). "The shear strength of partly saturated soils". Géotechnique. 36 (3): 453–456. doi:10.1680/geot.1986.36.3.453. ISSN 0016-8505. Retrieved 12 April 2024 – via Institution of Civil Engineers Virtual Library.
- Bishop, A. W.; Blight, G. E. (1963). "Some Aspects of Effective Stress in Saturated and Partly Saturated Soils". Géotechnique. 13 (3): 177–197. doi:10.1680/geot.1963.13.3.177. ISSN 0016-8505. Retrieved 12 April 2024 – via Institution of Civil Engineers Virtual Library.
- Sridharan, A.; Rao, G. Venkatappa; Pandian, R. Samudra (1973). "Volume Change Behaviour of Partly Saturated Clays During Soaking and the Role of Effective Stress Concept". Soils and Foundations. 13 (3): 1–15. doi:10.3208/sandf1972.13.3_1. Retrieved 12 April 2024 – via Science Direct.
- "Geo-Engineering at Durham University".
- "Groundwater". fbe.uwe.ac.uk. Archived from the original on September 2, 2006.
- "Capillary Aging of the Contacts between Glass Spheres and a Quartz Resonator Surface" (PDF). home.tu-clausthal.de. Archived from the original (PDF) on May 30, 2008.
- Terzaghi, K. (1925). Principles of Soil Mechanics. Engineering News-Record, 95(19-27).
The effective stress can be defined as the stress depending on the applied tension sij displaystyle boldsymbol sigma ij and pore pressure p displaystyle p which controls the strain or strength behaviour of soil and rock or a generic porous body for whatever pore pressure value or in other terms the stress which applied over a dry porous body i e at p 0 displaystyle p 0 provides the same strain or strength behaviour which is observed at p displaystyle p 0 In the case of granular media it can be viewed as a force that keeps a collection of particles rigid Usually this applies to sand soil or gravel as well as every kind of rock and several other porous materials such as concrete metal powders biological tissues etc The usefulness of an appropriate ESP formulation consists in allowing to assess the behaviour of a porous body for whatever pore pressure value on the basis of experiments involving dry samples i e carried out at zero pore pressure Erg Chebbi MoroccoHistoryKarl von Terzaghi first proposed the relationship for effective stress in 1925 For him the term effective meant the calculated stress that was effective in moving soil or causing displacements It has been often interpreted as the average stress carried by the Afterwards different formulations have been proposed for the effective stress Maurice Biot fully developed the three dimensional soil consolidation theory extending the one dimensional model previously developed by Terzaghi to more general hypotheses and introducing the set of basic equations of Poroelasticity Alec Skempton in his work in 1960 has carried out an extensive review of available formulations and experimental data in literature about effective stress valid in soil concrete and rock in order to reject some of these expressions as well as clarify what expression was appropriate according to several work hypotheses such as stress strain or strength behaviour saturated or nonsaturated media rock concrete or soil behaviour etc In 1962 work by Jeremiah Jennings and John Burland examined the applicability of Terzaghi s effective stress principle to partly saturated soils Through a series of experiments undertaken at the University of the Witwatersrand including oedometer and compression tests on various soil types they showed that behaviours such as volume changes and shear strength in partly saturated soils do not align with predictions based on effective stress changes alone Their findings showed that the structural changes due to pressure deficiencies behave differently from changes due to applied stress DescriptionEffective stress s acting on a soil is calculated from two parameters total stress s and pore water pressure u according to s s u displaystyle sigma sigma u Typically for simple examples s Hsoilgsoilu Hwgw displaystyle begin aligned sigma amp H mathrm soil gamma mathrm soil u amp H mathrm w gamma mathrm w end aligned Much like the concept of stress itself the formula is a construct for the easier visualization of forces acting on a soil mass especially simple analysis models for slope stability involving a slip plane With these models it is important to know the total weight of the soil above including water and the pore water pressure within the slip plane assuming it is acting as a confined layer citation needed However the formula becomes confusing when considering the true behaviour of the soil particles under different measurable conditions since none of the parameters are actually independent actors on the particles citation needed Arrangement of Spheres showing contacts Consider a grouping of round quartz sand grains piled loosely in a classic cannonball arrangement As can be seen there is a contact stress where the spheres actually touch Pile on more spheres and the contact stresses increase to the point of causing frictional instability dynamic friction and perhaps failure The independent parameter affecting the contacts both normal and shear is the force of the spheres above This can be calculated by using the overall average density of the spheres and the height of spheres above citation needed Spheres immersed in water reducing effective stress If we then have these spheres in a beaker and add some water they will begin to float a little depending on their density buoyancy With natural soil materials the effect can be significant as anyone who has lifted a large rock out of a lake can attest The contact stress on the spheres decreases as the beaker is filled to the top of the spheres but then nothing changes if more water is added Although the water pressure between the spheres pore water pressure is increasing the effective stress remains the same because the concept of total stress includes the weight of all the water above This is where the equation can become confusing and the effective stress can be calculated using the buoyant density of the spheres soil and the height of the soil above citation needed Spheres being injected with water reducing effective stress The concept of effective stress truly becomes interesting when dealing with non hydrostatic pore water pressure Under the conditions of a pore pressure gradient the ground water flows according to the permeability equation Darcy s law Using our spheres as a model this is the same as injecting or withdrawing water between the spheres If water is being injected the seepage force acts to separate the spheres and reduces the effective stress Thus the soil mass becomes weaker If water is being withdrawn the spheres are forced together and the effective stress increases Two extremes of this effect are quicksand where the groundwater gradient and seepage force act against gravity and the sandcastle effect where the water drainage and capillary action act to strengthen the sand As well effective stress plays an important role in slope stability and other geotechnical engineering and engineering geology problems such as groundwater related subsidence ReferencesGuerriero V Mazzoli S 2021 Theory of Effective Stress in Soil and Rock and Implications for Fracturing Processes A Review Geosciences 11 3 119 Bibcode 2021Geosc 11 119G doi 10 3390 geosciences11030119 Terzaghi Karl 1925 Erdbaumechanik auf Bodenphysikalischer Grundlage F Deuticke Terzaghi Karl 1936 Relation Between Soil Mechanics and Foundation Engineering Presidential Address Proceedings First International Conference on Soil Mechanics and Foundation Engineering Boston 3 13 18 Vertical stress in the ground fbe uwe ac uk Archived from the original on June 18 2006 Skempton A W 1984 01 01 Effective Stress in Soils Concrete and Rocks SELECTED PAPERS ON SOIL MECHANICS Thomas Telford Publishing pp 106 118 doi 10 1680 sposm 02050 0014 ISBN 978 0 7277 3982 7 retrieved 2023 04 11 Jennings J E B Burland J B 1962 Limitations to the Use of Effective Stresses in Partly Saturated Soils Geotechnique 12 2 125 144 doi 10 1680 geot 1962 12 2 125 ISSN 0016 8505 Retrieved 12 April 2024 via Institution of Civil Engineers Virtual Library Escario V Saez J 1986 The shear strength of partly saturated soils Geotechnique 36 3 453 456 doi 10 1680 geot 1986 36 3 453 ISSN 0016 8505 Retrieved 12 April 2024 via Institution of Civil Engineers Virtual Library Bishop A W Blight G E 1963 Some Aspects of Effective Stress in Saturated and Partly Saturated Soils Geotechnique 13 3 177 197 doi 10 1680 geot 1963 13 3 177 ISSN 0016 8505 Retrieved 12 April 2024 via Institution of Civil Engineers Virtual Library Sridharan A Rao G Venkatappa Pandian R Samudra 1973 Volume Change Behaviour of Partly Saturated Clays During Soaking and the Role of Effective Stress Concept Soils and Foundations 13 3 1 15 doi 10 3208 sandf1972 13 3 1 Retrieved 12 April 2024 via Science Direct Geo Engineering at Durham University Groundwater fbe uwe ac uk Archived from the original on September 2 2006 Capillary Aging of the Contacts between Glass Spheres and a Quartz Resonator Surface PDF home tu clausthal de Archived from the original PDF on May 30 2008 Terzaghi K 1925 Principles of Soil Mechanics Engineering News Record 95 19 27 Wikimedia Commons has media related to Effective stress
