Seismic speed traps: iron-rich regions may slow deep-earth vibes.Large quantities of iron-rich minerals may be responsible for the sluggishness of seismic waves traveling through certain regions deep within Earth, a new analysis suggests. About 2,900 kilometers below Earth's surface Noun 1. Earth's surface - the outermost level of the land or sea; "earthquakes originate far below the surface"; "three quarters of the Earth's surface is covered by water" surface , molten iron from the planet's core meets a thick, overlying overlying suffocation of piglets by the sow. The piglets may be weak from illness or malnutrition, the sow may be clumsy or ill, the pen may be inadequate in size or poorly designed so that piglets cannot escape. mantle of silicate minerals The silicate minerals make up the largest and most important class of rock-forming minerals. They are classified based on the structure of their silicate ion group. Subclasses: Nesosilicates or Isosilicates Nesosilicates (or orthosilicates . Vibrations spreading from large earthquakes slow significantly as they pass through some patches of rock just above that core-mantle boundary, says Ho-kwang Mao Ho-Kwang (Dave) Mao is a staff scientist at the Geophysical Laboratory of the Carnegie Institution of Washington. He is one of the most prolific users of the diamond anvil cell for research at high pressures. , a geophysicist at the Carnegie Institution of Washington  The introduction to this article may be too long. Please help improve the introduction by moving some material from it into the body of the article according to the suggestions at (D.C.). Those regions, dubbed ultralow-velocity zones, range between 5 and 40 km thick and can measure more than 100 km across. Earthquakes cause a variety of vibrations, including seismic-pressure waves that travel through the ground as sound does through air and other waves that transfer shearing stresses through rock. In ultralow-velocity zones, seismic pressure waves slow 5 to 10 percent, sws Mao. Shear waves can be hindered by as much as 30 percent. Because liquids can't transmit shear waves, scientists previously speculated that partial melting of minerals in the zones was responsible for the seismic-wave slowdown, he notes. Now, Mao and his colleagues oiler another explanation: high iron content. The researchers performed lab tests on samples of an iron-rich silicate silicate, chemical compound containing silicon, oxygen, and one or more metals, e.g., aluminum, barium, beryllium, calcium, iron, magnesium, manganese, potassium, sodium, or zirconium. Silicates may be considered chemically as salts of the various silicic acids. having a particular crystal structure, called a postperovskite phase, that scientists presume occurs near the core-mantle boundary. The silicate contained more than twice as much iron as other silicate-crystal structures can hold. When the researchers squeezed the mineral to the pressure expected near the coremantle boundary--almost 1.3 million times that exerted by the atmosphere at sea level-they noted that vibrations traveling through the sample slowed considerably. "Pressure waves traveled 7 percent slower than expected, and shear waves progressed about 30 percent slower," says Mao. The researchers report their findings in the April 28 Science. The idea that iron-rich minerals cause seismic slowdown is intriguing, says Michael Thorne, a seismologist seis·mol·o·gy n. The geophysical science of earthquakes and the mechanical properties of the earth. seis at the University of Alaska in Fairbanks. High iron concentrations could also explain the high density of minerals inferred from past observations of ultralow-velocity zones, he notes. Large concentrations of iron-bearing minerals provide an interesting potential explanation of the seismic slowdown in the ultra-low-velocity zones, says John Hernlund of the Paris Geophysical Institute The Geophysical Institute of the University of Alaska Fairbanks conducts research into space physics and aeronomy; atmospheric sciences; snow, ice, and permafrost; seismology; volcanology; and tectonics and sedimentation. It was founded in 1946 by the United States Congress. . This "iron-sponge" scenario is more feasible than that of partially melted minerals because it doesn't require the ultralow-velocity zones to be mixtures of melted and solid minerals, he adds. Such areas, especially in layers 40 Km thick, probably wouldn't have been as stable over geologic time as ultralow-density zones seem to have been. |
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