7.4 Elastic waves: P-waves and S-waves
Give an elastic solid its equation of motion and it supports waves — two kinds, travelling at two speeds. The compressional wave carries changes of volume; the shear wave carries changes of shape. That a solid supports both, while a fluid supports only the first, is the central diagnostic of seismology and the sharpest expression of what elasticity adds over fluid mechanics.
The Navier–Cauchy equation
Apply Newton’s second law to a small element of the continuum. The net force per unit volume is the divergence of the stress tensor, so
▶ Substituting Hooke's law Derivation
Insert the isotropic constitutive law and use . Taking the divergence, the volumetric term contributes and the shear term contributes . Collecting,
This is the Navier–Cauchy equation, the equation of motion of an isotropic elastic solid.
Two waves from the Helmholtz decomposition
Any vector field splits into a curl-free part and a divergence-free part. Applied to the displacement, this separates the Navier–Cauchy equation into two independent wave equations.
▶ Longitudinal and transverse waves Derivation
Write with (longitudinal) and (transverse). For the longitudinal part , so the equation becomes . For the transverse part , so the first term drops and . Each is a wave equation, with speed the square root of the stiffness over density.
The two speeds are
- P-wave (longitudinal) speed m/s
- S-wave (shear) speed m/s
- bulk modulus Pa
- shear modulus Pa
- mass density kg/m³
The P-wave (top) is compressional: particles oscillate *along* the propagation direction; the medium alternately compresses and rarefies. The S-wave (bottom) is shear: particles oscillate *perpendicular* to the propagation direction. P-waves are always faster (involve both K and G); S-waves involve only G — they don't exist in fluids (where G = 0). The c_P / c_S ratio is always > √2 and diverges as the material approaches incompressibility.
The P-wave (primary, longitudinal) is compressional: particles oscillate along the propagation direction, and both the bulk modulus and shear modulus resist the motion. The S-wave (secondary, shear) is transverse: particles oscillate across the propagation direction, resisted by alone. Since carries the extra under the root, the P-wave is always faster — it arrives first, which is how it earned its name.
Fluids, solids, and seismology
A fluid has : no shear stiffness, hence no shear wave. It transmits only the compressional wave, at speed — the ordinary speed of sound in a liquid or gas. A solid, carrying both, is distinguished precisely by its ability to transmit shear.
The consequence organises seismology. For steel (, , ), and . An earthquake radiates both; because they travel at different speeds, the P-wave outruns the S-wave, and the P–S arrival delay at a seismometer grows linearly with distance to the source — the basic ruler for locating an earthquake. And because the Earth’s liquid outer core kills the S-wave, the shadow it casts across the far side revealed the core to be molten.