5.3 Elasticity: stress and strain

Learning objectives

By the end of this section, you will be able to:

• State Hooke's law.
• Explain Hooke's law using graphical representation between deformation and applied force.
• Discuss the three types of deformations such as changes in length, sideways shear, and changes in volume.
• Describe with examples the Young's modulus, shear modulus, and bulk modulus.
• Determine the change in length given mass, length, and radius.

We now move from consideration of forces that affect the motion of an object (such as friction and drag) to those that affect an object's shape. If a bulldozer pushes a car into a wall, the car will not move but it will noticeably change shape. A change in shape due to the application of a force is a deformation    . Even very small forces are known to cause some deformation. For small deformations, two important characteristics are observed. First, the object returns to its original shape when the force is removed—that is, the deformation is elastic for small deformations. Second, the size of the deformation is proportional to the force—that is, for small deformations, Hooke's law is obeyed. In equation form, Hooke's law    is given by

where $\mathrm{\Delta }L$ is the amount of deformation (the change in length, for example) produced by the force $F$ , and $k$ is a proportionality constant that depends on the shape and composition of the object and the direction of the force. Note that this force is a function of the deformation $\mathrm{\Delta }L$ —it is not constant as a kinetic friction force is. Rearranging this to

makes it clear that the deformation is proportional to the applied force. [link] shows the Hooke's law relationship between the extension $\mathrm{\Delta }L$ of a spring or of a human bone. For metals or springs, the straight line region in which Hooke's law pertains is much larger. Bones are brittle and the elastic region is small and the fracture abrupt. Eventually a large enough stress to the material will cause it to break or fracture.

The proportionality constant $k$ depends upon a number of factors for the material. For example, a guitar string made of nylon stretches when it is tightened, and the elongation $\mathrm{\Delta }L$ is proportional to the force applied (at least for small deformations). Thicker nylon strings and ones made of steel stretch less for the same applied force, implying they have a larger $k$ (see [link] ). Finally, all three strings return to their normal lengths when the force is removed, provided the deformation is small. Most materials will behave in this manner if the deformation is less than about 0.1% or about 1 part in ${\text{10}}^3$ .