S-wave

This MedLibrary.org supplementary page on S-wave is provided directly from the open source Wikipedia as a service to our readers. Please see the note below on authorship of this content, as well as the Wikipedia usage guidelines. To search for other content from our encyclopedia supplement, please use the form below:

Related Sponsors

BM Pharmacy Generic pharmaceuticals at unbeatable prices. Insomnia, men's health, hair health, pain control. bmpharmacy.com

Online Pharmacy Carisoprodol, tadalafil, sildenafil, vardenafil and more... xlpharmacy.com

MedBasket.com Discreet. Inexpensive. Fast shipping. Great selection. What more can we say? medbasket.com

Frugalmed 2000 reasons to shop with us first. frugalmed.com

Ads by Tiva

Plane shear wave

Propagation of a spherical S-wave in a 2d grid (empirical model)

S-wave can also refer to the lowest energy electronic wavefunction in atomic physics; see atomic orbital.

A type of seismic wave, the S-wave, secondary wave, or shear wave (sometimes called an elastic S-wave) is one of the two main types of elastic body waves, so named because they move through the body of an object, unlike surface waves.

The S-wave move as a shear or transverse wave, so motion is perpendicular to the direction of wave propagation: S-waves, like waves in a rope, as opposed to waves moving through a slinky, the P-wave. The wave moves through elastic media, and the main restoring force comes from shear effects. These waves are divergenceless and obey the continuity equation for incompressible media:

$\nabla \cdot \mathbf{u}=0$

the S-wave shadow zone extends from the border of the P-wave shadow zone (at 104° away from the epicenter), and covers the entire section of the Earth beyond 104°. (from USGS)

Its name, S for secondary, comes from the fact that it is the second direct arrival on an earthquake seismogram, after the compressional primary wave, or P-wave. Unlike the P-wave, the S-wave cannot travel through the molten outer core of the Earth, and this causes a shadow zone for S-waves opposite to where they originate. They can still appear in the solid inner core: when a P-wave strikes the boundary of molten and solid cores, called the Lehmann discontinuity, S-waves will then propagate in the solid medium. And when the S-waves hit the boundary again they will in turn create P-waves. In fact, this property allows seismologists to determine the nature of the inner core.

The velocity of an S-wave in an isotropic medium can be described by the shear modulus $μ$ and density $ρ$ .

$v_S=\sqrt{\frac{\mu}{\rho}}$

As transverse waves, S-waves exhibit properties, such as polarization and birefringence, much like other transverse waves. S-waves polarized in the horizontal plane are classified as SH-waves. If polarized in the vertical plane, they are classified as SV-waves. When an S- or P-wave strikes an interface at an angle other than 90 degrees, a phenomenon known as mode conversion occurs. As described above, if the interface is between a solid and liquid, S becomes P or vice versa. However, even if the interface is between two solid media, mode conversion results. If a P-wave strikes an interface, four propagation modes may result: reflected and transmitted P and reflected and transmitted SV. Similarly, if an SV-wave strikes an interface, the same four modes occur in different proportions. The exact amplitudes of all these waves are described by the Zoeppritz equations, which in turn are solutions to the wave equation.

v • d • e Topics in geotechnical engineering

Soils	Clay · Silt · Sand · Gravel · Peat

Soil properties	Hydraulic conductivity · Water content · Void ratio · Bulk density · Thixotropy · Reynolds' dilatancy · Angle of repose · Cohesion · Porosity · Permeability · Specific storage

Soil mechanics	Effective stress · Pore water pressure · Shear strength · Overburden pressure · Consolidation · Soil compaction · Soil classification · Shear wave · Lateral earth pressure

Geotechnical investigation	Cone penetration test · Standard penetration test · Exploration geophysics · Monitoring well · Borehole

Laboratory tests	Atterberg limits · California bearing ratio · Direct shear test · Hydrometer · Proctor compaction test · R-value · Sieve analysis · Triaxial shear test · Hydraulic conductivity tests · Water content tests

Field tests	Crosshole sonic logging · Nuclear Densometer Test

Foundations	Bearing capacity · Shallow foundation · Deep foundation · Dynamic load testing · Wave equation analysis

Retaining walls	Mechanically stabilized earth · Soil nailing · Tieback · Gabion · Slurry wall

Slope stability	Mass wasting · Landslide

Earthquakes	Soil liquefaction · Response spectrum · Seismic hazard · Ground-structure interaction

Geosynthetics	Geotextile · Geomembranes · Geosynthetic clay liner

Instrumentation for Stability Monitoring	Deformation monitoring · Automated Deformation Monitoring

Wikipedia content modification information:

This page was last modified on 24 November 2008, at 17:19.

Wikipedia Authorship and Review

Wikipedia content provided here is not reviewed directly by MedLibrary.org. Wikipedia content is authored by an open community of volunteers and is not produced by or in any way affiliated with MedLibrary.org.

Wikipedia Usage Guidelines

This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article on "S-wave".

The URL for this specific entry is:

http://medlibrary.org/medwiki/S-wave

All Wikipedia text is available under the terms of the GNU Free Documentation License. (See Copyrights for details). Wikipedia® is a registered trademark of the Wikimedia Foundation, Inc.

Welcome to the MedLibrary.org Wikipedia Supplement on S-wave -- Please Click to Return to Front Page

S-wave

Related Sponsors

See also

Further reading

Wikipedia Authorship and Review

Wikipedia Usage Guidelines

Site Menu