Among the many types of seismic waves, one can make a broad distinction between
body waves, which travel through the Earth, and
surface waves, which travel at the Earth's surface. Other modes of wave propagation exist than those described in this article; though of comparatively minor importance for earth-borne waves, they are important in the case of
asteroseismology. • Body waves travel through the interior of the Earth. • Surface waves travel across the surface. Surface waves decay more slowly with distance than body waves which travel in three dimensions. • Particle motion of surface waves is larger than that of body waves, so surface waves tend to cause more damage.
Body waves Body waves travel through the interior of the Earth along paths controlled by the material properties in terms of
density and
modulus (stiffness). The density and modulus, in turn, vary according to temperature, composition, and material phase. This effect resembles the
refraction of
light waves. Two types of particle motion result in two types of body waves:
Primary and
Secondary waves. This distinction was recognized in 1830 by the French mathematician
Siméon Denis Poisson.
Primary waves Primary waves (P waves) are compressional waves that are
longitudinal in nature.
P waves are pressure waves that travel faster than other waves through the earth to arrive at seismograph stations first, hence the name "Primary". These waves can travel through any type of material, including fluids, and can travel nearly 1.7 times faster than the
S waves. In air, they take the form of sound waves, hence they travel at the
speed of sound. Typical speeds are 330 m/s in air, 1450 m/s in water and about 5000 m/s in
granite.
Secondary waves Secondary waves (S waves) are shear waves that are
transverse in nature. Following an earthquake event, S waves arrive at seismograph stations after the faster-moving P waves and displace the ground perpendicular to the direction of propagation. Depending on the propagational direction, the wave can take on different surface characteristics; for example, in the case of horizontally polarized S waves, the ground moves alternately to one side and then the other. S waves can travel only through solids, as fluids (liquids and gases) do not support
shear stresses. S waves are slower than P waves, and speeds are typically around 60% of that of P waves in any given material. Shear waves can not travel through any liquid medium, so the absence of S waves in earth's outer core suggests a liquid state.
Surface waves Seismic surface waves travel along the Earth's surface. They can be classified as a form of
mechanical surface wave. Surface waves diminish in amplitude as they get farther from the surface and propagate more slowly than seismic body waves (P and S). Surface waves from very large earthquakes can have globally observable amplitude of several centimeters.
Rayleigh waves Rayleigh waves, also called ground roll, are surface waves that propagate with motions that are similar to those of waves on the surface of water (note, however, that the associated seismic particle motion at shallow depths is typically retrograde, and that the restoring force in Rayleigh and in other seismic waves is elastic, not gravitational as for water waves). The existence of these waves was predicted by John William Strutt,
Lord Rayleigh, in 1885. They are slower than body waves, e.g., at roughly 90% of the velocity of S waves for typical homogeneous elastic media. In a layered medium (e.g., the crust and
upper mantle) the velocity of the Rayleigh waves depends on their frequency and wavelength. See also
Lamb waves.
Love waves Love waves are horizontally
polarized shear waves (SH waves), existing only in the presence of a layered medium. They are named after
Augustus Edward Hough Love, a British mathematician who created a mathematical model of the waves in 1911. They usually travel slightly faster than Rayleigh waves, about 90% of the S wave velocity.
Stoneley waves A Stoneley wave is a type of boundary wave (or interface wave) that propagates along a solid-fluid boundary or, under specific conditions, also along a solid-solid boundary. Amplitudes of Stoneley waves have their maximum values at the boundary between the two contacting media and decay exponentially away from the contact. These waves can also be generated along the walls of a fluid-filled
borehole, being an important source of coherent noise in
vertical seismic profiles (VSP) and making up the low frequency component of the source in
sonic logging. The equation for Stoneley waves was first given by Dr. Robert Stoneley (1894–1976), emeritus professor of seismology, Cambridge.
Normal modes Free oscillations of the Earth are
standing waves, the result of interference between two surface waves traveling in opposite directions. Interference of Rayleigh waves results in
spheroidal oscillation S while interference of Love waves gives
toroidal oscillation T. The modes of oscillations are specified by three numbers, e.g., nSlm, where
l is the angular order number (or
spherical harmonic degree, see
Spherical harmonics for more details). The number
m is the azimuthal order number. It may take on 2
l+1 values from −
l to +
l. The number
n is the
radial order number. It means the wave with
n zero crossings in radius. For spherically symmetric Earth the period for given
n and
l does not depend on
m. Some examples of spheroidal oscillations are the "breathing" mode 0S0, which involves an expansion and contraction of the whole Earth, and has a period of about 20 minutes; and the "rugby" mode 0S2, which involves expansions along two alternating directions, and has a period of about 54 minutes. The mode 0S1 does not exist because it would require a change in the center of gravity, which would require an external force. Of the fundamental toroidal modes, 0T1 represents changes in Earth's rotation rate; although this occurs, it is much too slow to be useful in seismology. The mode 0T2 describes a twisting of the northern and southern hemispheres relative to each other; it has a period of about 44 minutes. The first observations of free oscillations of the Earth were done during the great
1960 earthquake in Chile. Presently the periods of thousands of modes have been observed. These data are used for constraining large scale structures of the Earth's interior.
P and S waves in Earth's mantle and core When an earthquake occurs, seismographs near the
epicenter are able to record both P and S waves, but those at a greater distance no longer detect the high frequencies of the first S wave. Since shear waves cannot pass through liquids, this phenomenon was original evidence for the now well-established observation that the Earth has a liquid
outer core, as demonstrated by
Richard Dixon Oldham. This kind of observation has also been used to argue, by
seismic testing, that the
Moon has a solid core, although recent geodetic studies suggest the core is still molten. == Notation ==