9.1 Stress and Strain

Figure 9.1.1: Depiction of the stress applied to rocks within the crust. The stress can be broken down into three components. Assuming that we’re looking down in this case, the green arrows represent north-south stress, the red arrows represent east-west stress, and the blue arrows (the one underneath is not visible) represent up-down stress. On the left, all of the stress components are the same. On the right, the north-south stress is least and the up-down stress is greatest.

Rocks are subject to stress—mostly related to plate tectonics but also to the weight of overlying rocks—and their response to that stress is strain (sometimes called deformation).  In regions close to where plates are converging stress is typically compressional—the rocks are being squeezed.  Where plates are diverging the stress is tensional—rocks are being pulled apart.  At transform plate boundaries, where plates are moving side by side there is sideways or shear stress—meaning that there are forces in opposite directions parallel to a plane. Rocks have highly varying strain responses to stress because of their different compositions and physical properties, and because temperature is a big factor and rock temperatures within the crust can vary greatly.

We can describe the stress applied to a rock by breaking it down into three dimensions—all at right angles to one-another (Figure 9.1.1). If the rock is subject only to the pressure of burial, the stresses in all three directions will likely be the same.  If it is subject to both burial and tectonic forces, the pressures will be different in different directions.

Figure 10.1.2: The varying types of response of geological materials to stress. The straight dashed parts are elastic strain and the curved parts are plastic strain. In each case the X marks where the material fractures. A, the strongest material, deforms relatively little and breaks at a high stress level. B, strong but brittle, shows no plastic deformation and breaks after relatively little elastic deformation. C, the most deformable, breaks only after significant elastic and plastic strain.  The three deformation diagrams on the right show A and C before breaking and B after breaking.
Figure 9.1.2: The varying types of response of geological materials to stress. The straight dashed parts are elastic strain and the curved parts are plastic strain. In each case the X marks where the material fractures. A, the strongest material, deforms relatively little and breaks at a high stress level. B, strong but brittle, shows no plastic deformation and breaks after relatively little elastic deformation. C, the most deformable, breaks only after significant elastic and plastic strain.  The three deformation diagrams on the right show A and C before breaking and B after breaking.

Rock can respond to stress in three ways: it can deform elastically, it can deform plastically, and it can break or fracture.  Elastic strain is reversible; if the stress is removed, the rock will return to its original shape just like a rubber band that is stretched and released. Plastic strain is not reversible. As already noted, different rocks at different temperatures will behave in different ways to stress. Higher temperatures lead to more plastic behaviour. Some rocks or sediments are also more plastic when they are wet.  Another factor is the rate at which the stress is applied.  If the stress is applied quickly (for example, because of an extraterrestrial impact or an earthquake), there will be an increased tendency for the rock to fracture. Some different types of strain response are illustrated in Figure 9.1.2.

The outcomes of placing rock under stress are highly variable, but they include fracturing, tilting and folding, stretching and squeezing, and faulting. A fracture is a simple break that does not involve significant movement of the rock on either side. Fracturing is particularly common in volcanic rock, which shrinks as it cools. The basalt columns in Figure 9.1.3a are a good example of fracture. Beds are sometimes tilted by tectonic forces, as shown in Figure 9.1.3b, or folded.

Figure 10.1.3: Rock structures caused by various types of strain within rocks that have been stressed. (A) Fracturing in basalt near to Whistler, BC; (B) Tilting of sedimentary rock near to Exshaw, Alberta; (C) Stretching of limestone at Quadra Island, BC. The light grey rock is limestone and the dark rock is chert. The body of rock has been stretched parallel to bedding. The chert, which is not elastic, has broken into fragments which are called boudins; (D) Faulting within shale beds at McAbee, near to Cache Creek, BC. The fault runs from the lower right to the upper left, and the upper rock body has been pushed up and to the left.
Figure 9.1.3: Rock structures caused by various types of strain within rocks that have been stressed.

When a body of rock is compressed in one direction it is typically extended (or stretched) in another.  This is an important concept because some geological structures only form under compressional stress, while others only form under tensional stress. Most of the rock in Figure 9.1.3c is limestone, which is relatively weak and easily deformed when heated. The dark rock is chert, which is relatively stronger and remains brittle. As the limestone stretched (parallel to the hammer handle) the brittle chert was forced to break into fragments to accommodate the change in shape of the body of rock. Figure 9.1.3d shows another type of brittle structure called a fault. Like fractures, faults result from brittle breaking of a rock unit. The key difference is that the bodies of rock on either side of the fault have been displaced relative to each other by the faulting.

Media Attributions

  • Figures 9.1.1, 9.1.2, 9.1.3: © Steven Earle. CC-BY-4.0.

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OLD - A Practical Guide to Introductory Geology (2023-2024 Edition) Copyright © 2022 by Matthew Minnett and Benjamin Daniels is licensed under a Creative Commons Attribution 4.0 International License, except where otherwise noted.

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