Do you know anything about the Earth's mantle?

Question

The Earth's mantle consists of two layers. I want to know the composition of each layer. Or rather, the distinguishing compositions of each layer.
Please, can you help me?

Answer 1

Earth's mantle is the thick shell of dense rock surrounding the liquid metallic Earth's outer core, and lies directly beneath the Earth's thin crust. The term is also applied to the rocky shell surrounding the cores of other planets. Earth's mantle lies roughly between 30 and 2,900 km below the surface, and occupies about 70% of Earth's volume.

STRUCTURE=The boundary between the crust and the mantle is the Mohorovičić discontinuity, named for its discoverer, and is usually called the Moho. The Seismic Moho is a boundary at which there is a sudden change in the speed of seismic waves, which can be detected by sensitive instruments at Earth's surface. At one time some people thought that the Moho was the structure along which the Earth's rigid crust moved relative to the mantle. Current research considers the motion of the crust associated with plate tectonics as the surface manifestation of a much deeper mantle circulation. The uppermost mantle just below the crust is composed of relatively cold and therefore strong material. This strong layer of mantle and the crust forms the lithosphere, and cools mainly by convection.

The subregion of the mantle extending about 250 km (155 mi) below the lithosphere is called the asthenosphere, this cools mainly by convection. In some regions of the earth, this subregion of the mantle is partly associated with a region of the mantle that passes seismic waves more slowly. This region is called the low-velocity zone. The cause of this low velocity zone is still debated. Currently theories include the influence of temperature and pressure or the existence of a small amount of partial melt.

Characteristics=The mantle differs substantially from the crust in its mechanical characteristics and its chemical composition. The distinction between crust and mantle is based on chemistry, rock types, and seismic characteristics. The crust is, in fact, primarily a product of mantle melting. Melting of mantle material is believed to cause incompatible minerals to separate, with less dense material floating upward. Typical mantle rocks have a higher portion of iron and magnesium, a higher magnesium to iron ratio, and a smaller portion of silicon and aluminium than the crust.
Mantle rock above about 400 km depth consists mostly of olivine, pyroxenes, spinel, and garnet: typical rock types are peridotite, dunite (olivine-rich peridotite), and eclogite. Between about 400 km and 650 km depth, olivine is not stable and is replaced by polymorphs with approximately the same composition: one polymorph is wadsleyite, and the other is ringwoodite (a mineral with the spinel structure). Below about 650 km, none of the minerals of the upper mantle is stable; the most abundant minerals present have structures (but not compositions) like that of the mineral, perovskite. The changes in mineralogy at about 400 and 650 km yield distinctive signatures in seismic records of the Earth's interior. These changes in mineralogy may influence mantle convection, as they result in density changes and they may absorb or release heat during phase transitions in convecting mantle. The changes in mineralogy with depth have been investigated by laboratory experiments that duplicate high mantle pressures, such as those using the diamond anvil.

Temperature=In the mantle, temperatures range between 1000°C at the upper boundary to over 4,000°C at the boundary with the core. Although these temperatures far exceed the melting points of the mantle rocks at the surface, particularly in deeper ranges, they are almost exclusively solid. The enormous lithostatic pressure exerted on the mantle prevents them from melting.
The subregion of the mantle extending about 250 km (155 mi) below the lithosphere is called the asthenosphere; this cools mainly by convection.

Due to the temperature difference between the Earth's surface and outer core there is a convective material circulation in the mantle. Hot material ascends as a plutonic diapir from the border with the outer core, while cooler (and heavier) material sinks downward. This is often in the form of large-scale lithospheric downwellings at plate boundaries called subduction zones. During the ascent the material of the mantle cools down adiabatically. The temperature of the material falls with the pressure relief connected with the ascent, and its heat distributes itself over a larger volume. Near the lithosphere the pressure relief can lead to partial melting of the diapir, leading to volcanism and plutonism.

The convection of the Earth's mantle is a chaotic process (in the sense of fluid dynamics), which is thought to be an integral part of the motion of plates. Plate motion should not be confused with the older term continental drift which applies purely to the movement of the crustal components of the continents. The movements of the lithosphere and the underlying mantle are coupled since descending lithosphere is the dominant driving force for convection in the mantle. The observed continental drift is a complicated relationship between the forces causing oceanic lithosphere to sink and the movements within Earth's mantle. The convection of the mantle is not yet clarified in detail.

Although there is a tendency to larger viscosity at greater depth, this relation is far from linear, and shows layers with dramatically decreased viscosity, in particular in the upper mantle and at the boundary with the core [1]. The mantle within about 200 km above the core-mantle boundary appears to have distinctly different seismic properties than the mantle at slightly shallower depths; this unusual mantle region just above the core is called D″ ("D double-prime" or "D prime prime"). D″ may consist of material from subducted slabs that descended and came to rest at the core-mantle boundary.

Due to the relatively low viscosity in the upper mantle one could reason that there should be no earthquakes below approximately 300 km depth. However, in subduction zones, the geothermal gradient can be lowered, increasing the strength of the surrounding mantle, and allowing earthquakes to occur down to a depth of 400 km and 670 km.

The pressure at the bottom of the mantle is ~136 GPa (1.4 Matm). There exists increasing pressure as one travels deeper into the mantle. The entire mantle, however, is still thought to deform like a fluid on long timescales, with permanent plastic deformation accommodated by the movement of point, line, and planar defects through the solid crystals comprising the mantle. The viscosity of the upper mantle ranges between 1019 and 1024 Pa·s, depending on depth [1]. Thus, the upper mantle can only flow very slowly. However, when large forces are applied to the uppermost mantle it can become weaker, and this effect is thought to be important in allowing the formation of tectonic plate boundaries.

Exploration=The second attempt to retrieve samples from the Earth's mantle is scheduled for 2007 [2]. As part of the Chikyu Hakken mission, it will use the Japanese vessel 'Chikyu' to drill up to 7000m (23,000 ft) below the seabed. This is nearly three times as deep as preceding oceanic drillings, which are preferred over land drillings because the crust at the seabed is thinner. The first attempt, known as Project Mohole, was abandoned in 1966 after repeated failures and ever rising costs. The deepest they managed to penetrate was about 180m (590 ft). In 2005 the third-deepest oceanic borehole hole reached 1416 meters (4,644 feet) below the sea floor from the ocean drilling vessel JOIDES Resolution.

Movement=
The subregion of the mantle extending about 250 km (155 mi) below the lithosphere is called the asthenosphere; this cools mainly by convection.

Due to the temperature difference between the Earth's surface and outer core there is a convective material circulation in the mantle. Hot material ascends as a plutonic diapir from the border with the outer core, while cooler (and heavier) material sinks downward. This is often in the form of large-scale lithospheric downwellings at plate boundaries called subduction zones. During the ascent the material of the mantle cools down adiabatically. The temperature of the material falls with the pressure relief connected with the ascent, and its heat distributes itself over a larger volume. Near the lithosphere the pressure relief can lead to partial melting of the diapir, leading to volcanism and plutonism.

The convection of the Earth's mantle is a chaotic process (in the sense of fluid dynamics), which is thought to be an integral part of the motion of plates. Plate motion should not be confused with the older term continental drift which applies purely to the movement of the crustal components of the continents. The movements of the lithosphere and the underlying mantle are coupled since descending lithosphere is the dominant driving force for convection in the mantle. The observed continental drift is a complicated relationship between the forces causing oceanic lithosphere to sink and the movements within Earth's mantle. The convection of the mantle is not yet clarified in detail.

Although there is a tendency to larger viscosity at greater depth, this relation is far from linear, and shows layers with dramatically decreased viscosity, in particular in the upper mantle and at the boundary with the core [1]. The mantle within about 200 km above the core-mantle boundary appears to have distinctly different seismic properties than the mantle at slightly shallower depths; this unusual mantle region just above the core is called D″ ("D double-prime" or "D prime prime"). D″ may consist of material from subducted slabs that descended and came to rest at the core-mantle boundary.

Due to the relatively low viscosity in the upper mantle one could reason that there should be no earthquakes below approximately 300 km depth. However, in subduction zones, the geothermal gradient can be lowered, increasing the strength of the surrounding mantle, and allowing earthquakes to occur down to a depth of 400 km and 670 km.

The pressure at the bottom of the mantle is ~136 GPa (1.4 Matm). There exists increasing pressure as one travels deeper into the mantle. The entire mantle, however, is still thought to deform like a fluid on long timescales, with permanent plastic deformation accommodated by the movement of point, line, and planar defects through the solid crystals comprising the mantle. The viscosity of the upper mantle ranges between 1019 and 1024 Pa·s, depending on depth [1]. Thus, the upper mantle can only flow very slowly. However, when large forces are applied to the uppermost mantle it can become weaker, and this effect is thought to be important in allowing the formation of tectonic plate boundaries.

Answer 2

There's a clock on the mantle. Several, in fact.