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Upper mantle (Earth)

March 03, 2023

The upper mantle of Earth is a very thick layer of rock inside the planet, which begins just beneath the crust (at about 10 km (6.2 mi) under the oceans and about 35 km (22 mi) under the continents) and ends at the top of the lower mantle at 670 km (420 mi). Temperatures range from approximately 500 K (227 °C; 440 °F) at the upper boundary with the crust to approximately 1,200 K (930 °C; 1,700 °F) at the boundary with the lower mantle. Upper mantle material that has come up onto the surface comprises about 55% olivine, 35% pyroxene, and 5 to 10% of calcium oxide and aluminum oxide minerals such as plagioclase, spinel, or garnet, depending upon depth.

Seismic structure

 
1 = continental crust, 2 = oceanic crust, 3 = upper mantle, 4 = lower mantle, 5+6 = core, A = crust-mantle boundary (Mohorovičić discontinuity)

The density profile through Earth is determined by the velocity of seismic waves. Density increases progressively in each layer, largely due to compression of the rock at increased depths. Abrupt changes in density occur where the material composition changes.[1]

The upper mantle begins just beneath the crust and ends at the top of the lower mantle. The upper mantle causes the tectonic plates to move.

Crust and mantle are distinguished by composition, while the lithosphere and asthenosphere are defined by a change in mechanical properties.[2]

The top of the mantle is defined by a sudden increase in the speed of seismic waves, which Andrija Mohorovičić first noted in 1909; this boundary is now referred to as the Mohorovičić discontinuity or "Moho."[3]

The Moho defines the base of the crust and varies from 10 km (6.2 mi) to 70 km (43 mi) below the surface of the Earth. Oceanic crust is thinner than continental crust and is generally less than 10 km (6.2 mi) thick. Continental crust is about 35 km (22 mi) thick, but the large crustal root under the Tibetan Plateau is approximately 70 km (43 mi) thick.[4]

The thickness of the upper mantle is about 640 km (400 mi). The entire mantle is about 2,900 km (1,800 mi) thick, which means the upper mantle is only about 20% of the total mantle thickness.[4]

 
Cross-section of the Earth, showing the paths of earthquake waves. The paths curve because the different rock types found at different depths change the waves' speed. S waves do not travel through the core

The boundary between the upper and lower mantle is a 670 km (420 mi) discontinuity.[2] Earthquakes at shallow depths result from strike-slip faulting; however, below about 50 km (31 mi), the hot, high-pressure conditions inhibit further seismicity. The mantle is viscous and incapable of faulting. However, in subduction zones, earthquakes are observed down to 670 km (420 mi).[1]

Lehmann discontinuity

The Lehmann discontinuity is an abrupt increase of P-wave and S-wave velocities at a depth of 220 km (140 mi)[5] (Note that this is a different "Lehmann discontinuity" than the one between the Earth's inner and outer cores labeled in the image on the right.)

Transition zone

The transition zone is located between the upper mantle and the lower mantle between a depth of 410 km (250 mi) and 670 km (420 mi).

This is thought to occur as a result of the rearrangement of grains in olivine to form a denser crystal structure as a result of the increase in pressure with increasing depth.[6] Below a depth of 670 km (420 mi), due to pressure changes, ringwoodite minerals change into two new denser phases, bridgmanite and periclase. This can be seen using body waves from earthquakes, which are converted, reflected, or refracted at the boundary, and predicted from mineral physics, as the phase changes are temperature and density-dependent and hence depth-dependent.[6]

410 km discontinuity

A single peak is seen in all seismological data at 410 km (250 mi), which is predicted by the single transition from α- to β- Mg2SiO4 (olivine to wadsleyite). From the Clapeyron slope this discontinuity is expected to be shallower in cold regions, such as subducting slabs, and deeper in warmer regions, such as mantle plumes.[6]

670 km discontinuity

This is the most complex discontinuity and marks the boundary between the upper and lower mantle. It appears in PP precursors (a wave that reflects off the discontinuity once) only in certain regions but is always apparent in SS precursors.[6] It is seen as single and double reflections in receiver functions for P to S conversions over a broad range of depths (640–720 km, or 397–447 mi). The Clapeyron slope predicts a deeper discontinuity in colder regions and a shallower discontinuity in hotter regions.[6] This discontinuity is generally linked to the transition from ringwoodite to bridgmanite and periclase.[7] This is thermodynamically an endothermic reaction and creates a viscosity jump. Both characteristics cause this phase transition to playing an important role in geodynamical models.[8]

Other discontinuities

There is another major phase transition predicted at 520 km (320 mi) for the transition of olivine (β to γ) and garnet in the pyrolite mantle.[9] This one has only sporadically been observed in seismological data.[10]

Other non-global phase transitions have been suggested at a range of depths.[6][11]

Temperature and pressure

Temperatures range from approximately 500 K (227 °C; 440 °F) at the upper boundary with the crust to approximately 4,200 K (3,930 °C; 7,100 °F) at the core-mantle boundary.[12] The highest temperature of the upper mantle is 1,200 K (930 °C; 1,700 °F).[13] Although the high temperature far exceeds the melting points of the mantle rocks at the surface, the mantle is almost exclusively solid.[14]

The enormous lithostatic pressure exerted on the mantle prevents melting because the temperature at which melting begins (the solidus) increases with pressure.[15] Pressure increases as depth increases since the material beneath has to support the weight of all the material above it. The entire mantle is thought to deform like a fluid on long timescales, with permanent plastic deformation.

The highest pressure of the upper mantle is 24.0 GPa (237,000 atm)[13] compared to the bottom of the mantle, which is 136 GPa (1,340,000 atm).[12][16]

Estimates for the viscosity of the upper mantle range between 1019 and 1024 Pa·s, depending on depth,[17] temperature, composition, state of stress, and numerous other factors. 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.

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.[17]

Movement

Because of the temperature difference between the Earth's surface and outer core and the ability of the crystalline rocks at high pressure and temperature to undergo slow, creeping, viscous-like deformation over millions of years, there is a convective material circulation in the mantle.[3]

Hot material upwells, while cooler (and heavier) material sinks downward. Downward motion of material occurs at convergent plate boundaries called subduction zones. Locations on the surface that lie over plumes are predicted to have high elevation (because of the buoyancy of the hotter, less-dense plume beneath) and to exhibit hot spot volcanism.

Mineral composition

The seismic data is not sufficient to determine the composition of the mantle. Observations of rocks exposed on the surface and other evidence reveal that the upper mantle is mafic minerals olivine and pyroxene, and it has a density of about 3.33 g/cm3 (0.120 lb/cu in)[1]

Upper mantle material that has come up onto the surface comprises about 55% olivine and 35% pyroxene, and 5 to 10% of calcium oxide and aluminum oxide.[1] The upper mantle is dominantly peridotite, composed primarily of variable proportions of the minerals olivine, clinopyroxene, orthopyroxene, and an aluminous phase.[1] The aluminous phase is plagioclase in the uppermost mantle, then spinel, and then garnet below about 100 kilometres (62 mi).[1] Gradually through the upper mantle, pyroxenes become less stable and transform into majoritic garnet.

Experiments on olivines and pyroxenes show that these minerals change the structure as pressure increases at greater depth, which explains why the density curves are not perfectly smooth. When there is a conversion to a more dense mineral structure, the seismic velocity rises abruptly and creates a discontinuity.[1]

At the top of the transition zone, olivine undergoes isochemical phase transitions to wadsleyite and ringwoodite. Unlike nominally anhydrous olivine, these high-pressure olivine polymorphs have a large capacity to store water in their crystal structure. This has led to the hypothesis that the transition zone may host a large quantity of water.[18]

In Earth's interior, olivine occurs in the upper mantle at depths less than 410 kilometres (250 mi), and ringwoodite is inferred within the transition zone from about 520 to 670 kilometres (320 to 420 mi) depth. Seismic activity discontinuities at about 410 kilometres (250 mi), 520 kilometres (320 mi), and 670 kilometres (420 mi) depth have been attributed to phase changes involving olivine and its polymorphs.

At the base of the transition zone, ringwoodite decomposes into bridgmanite (formerly called magnesium silicate perovskite), and ferropericlase. Garnet also becomes unstable at or slightly below the base of the transition zone.

Kimberlites explode from the earth's interior and sometimes carry rock fragments. Some of these xenolithic fragments are diamonds that can only come from the higher pressures below the crust. The rocks that come with this are ultramafic nodules and peridotite.[1]

Chemical composition

The composition seems to be very similar to the crust. One difference is that rocks and minerals of the mantle tend to have more magnesium and less silicon and aluminum than the crust. The first four most abundant elements in the upper mantle are oxygen, magnesium, silicon, and iron.

Composition of the Earth's upper mantle (depleted MORB)[19][20]
Compound Mass percent
SiO2 44.71
MgO 38.73
FeO 8.18
Al2O3 3.98
CaO 3.17
Cr2O3 0.57
NiO 0.24
MnO 0.13
Na2O 0.13
TiO2 0.13
P2O5 0.019
K2O 0.006

Exploration

 
Chikyu drilling ship

Exploration of the mantle is generally conducted at the seabed rather than on land because of the oceanic crust's relative thinness as compared to the significantly thicker continental crust.

The first attempt at mantle exploration, known as Project Mohole, was abandoned in 1966 after repeated failures and cost overruns. The deepest penetration was approximately 180 m (590 ft). In 2005 an oceanic borehole reached 1,416 metres (4,646 ft) below the seafloor from the ocean drilling vessel JOIDES Resolution.

On 5 March 2007, a team of scientists on board the RRS James Cook embarked on a voyage to an area of the Atlantic seafloor where the mantle lies exposed without any crust covering, midway between the Cape Verde Islands and the Caribbean Sea. The exposed site lies approximately 3 kilometres (1.9 mi) beneath the ocean surface and covers thousands of square kilometers.[21][22][23]

The Chikyu Hakken mission attempted to use the Japanese vessel Chikyū to drill up to 7,000 m (23,000 ft) below the seabed. On 27 April 2012, Chikyū drilled to a depth of 7,740 metres (25,390 ft) below sea level, setting a new world record for deep-sea drilling. This record has since been surpassed by the ill-fated Deepwater Horizon mobile offshore drilling unit, operating on the Tiber prospect in the Mississippi Canyon Field, United States Gulf of Mexico, when it achieved a world record for total length for a vertical drilling string of 10,062 m (33,011 ft).[24] The previous record was held by the U.S. vessel Glomar Challenger, which in 1978 drilled to 7,049.5 meters (23,130 feet) below sea level in the Mariana Trench.[25] On 6 September 2012, Scientific deep-sea drilling vessel Chikyū set a new world record by drilling down and obtaining rock samples from deeper than 2,111 metres (6,926 ft) below the seafloor off the Shimokita Peninsula of Japan in the northwest Pacific Ocean.

A novel method of exploring the uppermost few hundred kilometers of the Earth was proposed in 2005, consisting of a small, dense, heat-generating probe that melts its way down through the crust and mantle while its position and progress are tracked by acoustic signals generated in the rocks.[26] The probe consists of an outer sphere of tungsten about 1 metre (3 ft 3 in) in diameter with a cobalt-60 interior acting as a radioactive heat source. This should take half a year to reach the oceanic Moho.[27]

Exploration can also be aided through computer simulations of the evolution of the mantle. In 2009, a supercomputer application provided new insight into the distribution of mineral deposits, especially isotopes of iron, from when the mantle developed 4.5 billion years ago.[28]

References

  1. ^ a b c d e f g h Langmuir, Charles H.; Broecker, Wally (2012-07-22). How to Build a Habitable Planet: The Story of Earth from the Big Bang to Humankind. pp. 179–183. ISBN 9780691140063.
  2. ^ a b Rothery, David A.; Gilmour, Iain; Sephton, Mark A. (March 2018). An Introduction to Astrobiology. p. 56. ISBN 9781108430838.
  3. ^ a b Alden, Andrew (2007). "Today's Mantle: a guided tour". About.com. Retrieved 2007-12-25.
  4. ^ a b "Istria on the Internet – Prominent Istrians – Andrija Mohorovicic". 2007. Retrieved 2007-12-25.
  5. ^ William Lowrie (1997). Fundamentals of geophysics. Cambridge University Press. p. 158. ISBN 0-521-46728-4.
  6. ^ a b c d e f Fowler, C. M. R.; Fowler, Connie May (2005). The Solid Earth: An Introduction to Global Geophysics. ISBN 978-0521893077.
  7. ^ Ito, E; Takahashi, E (1989). "Postspinel transformations in the system Mg2SiO4-Fe2SiO4 and some geophysical implications". Journal of Geophysical Research: Solid Earth. 94 (B8): 10637–10646. Bibcode:1989JGR....9410637I. doi:10.1029/jb094ib08p10637.
  8. ^ Fukao, Y.; Obayashi, M. (2013). "Subducted slabs stagnant above, penetrating through, and trapped below the 660 km discontinuity". Journal of Geophysical Research: Solid Earth. 118 (11): 5920–5938. Bibcode:2013JGRB..118.5920F. doi:10.1002/2013jb010466. S2CID 129872709.
  9. ^ Deuss, Arwen; Woodhouse, John (2001-10-12). "Seismic Observations of Splitting of the Mid-Transition Zone Discontinuity in Earth's Mantle". Science. 294 (5541): 354–357. Bibcode:2001Sci...294..354D. doi:10.1126/science.1063524. ISSN 0036-8075. PMID 11598296. S2CID 28563140.
  10. ^ Egorkin, A. V. (1997-01-01). "Evidence for 520-Km Discontinuity". In Fuchs, Karl (ed.). Upper Mantle Heterogeneities from Active and Passive Seismology. NATO ASI Series. Springer Netherlands. pp. 51–61. doi:10.1007/978-94-015-8979-6_4. ISBN 9789048149667.
  11. ^ Khan, Amir; Deschamps, Frédéric (2015-04-28). The Earth's Heterogeneous Mantle: A Geophysical, Geodynamical, and Geochemical Perspective. Springer. ISBN 9783319156279.
  12. ^ a b Lodders, Katharina (1998). The planetary scientist's companion. Fegley, Bruce. New York: Oxford University Press. ISBN 978-1423759836. OCLC 65171709.
  13. ^ a b "What Are Three Differences Between the Upper & Lower Mantle?". Sciencing. Retrieved 14 June 2019.
  14. ^ Louie, J. (1996). . University of Nevada, Reno. Archived from the original on 2011-07-20. Retrieved 2007-12-24.
  15. ^ Turcotte, DL; Schubert, G (2002). "4". Geodynamics (2nd ed.). Cambridge, England, UK: Cambridge University Press. pp. 136–7. ISBN 978-0-521-66624-4.
  16. ^ Burns, Roger George (1993). Mineralogical Applications of Crystal Field Theory. Cambridge University Press. p. 354. ISBN 978-0-521-43077-7. Retrieved 2007-12-26.
  17. ^ a b Walzer, Uwe. . Archived from the original on 2007-06-11.
  18. ^ Bercovici, David; Karato, Shun-ichiro (September 2003). "Whole-mantle convection and the transition-zone water filter". Nature. 425 (6953): 39–44. Bibcode:2003Natur.425...39B. doi:10.1038/nature01918. ISSN 0028-0836. PMID 12955133. S2CID 4428456.
  19. ^ Workman, Rhea K.; Hart, Stanley R. (February 2005). "Major and trace element composition of the depleted MORB mantle (DMM)". Earth and Planetary Science Letters. 231 (1–2): 53–72. Bibcode:2005E&PSL.231...53W. doi:10.1016/j.epsl.2004.12.005. ISSN 0012-821X.
  20. ^ Anderson, D.L. (2007). New Theory of the Earth. Cambridge University Press. p. 301. ISBN 9780521849593.
  21. ^ Than, Ker (2007-03-01). "Scientists to study gash on Atlantic seafloor". NBC News. Retrieved 2008-03-16. A team of scientists will embark on a voyage next week to study an "open wound" on the Atlantic seafloor where the Earth's deep interior lies exposed without any crust covering.
  22. ^ "Earth's Crust Missing In Mid-Atlantic". Science Daily. 2007-03-02. Retrieved 2008-03-16. Cardiff University scientists will shortly set sail (March 5) to investigate a startling discovery in the depths of the Atlantic.
  23. ^ . PhysOrg.com. 2005-12-15. Archived from the original on 2005-12-19. Retrieved 2008-03-16. An ambitious Japanese-led project to dig deeper into the Earth's surface than ever before will be a breakthrough in detecting earthquakes including Tokyo's dreaded "Big One," officials said Thursday.
  24. ^ . Archived from the original on 2011-10-17.
  25. ^ "Japan deep-sea drilling probe sets world record". The Kansas City Star. Associated Press. 28 April 2012. Archived from the original on 28 April 2012. Retrieved 28 April 2012.
  26. ^ Ojovan M.I., Gibb F.G.F., Poluektov P.P., Emets E.P. 2005. Probing of the interior layers of the Earth with self-sinking capsules. Atomic Energy, 99, 556–562
  27. ^ Ojovan M.I., Gibb F.G.F. "Exploring the Earth’s Crust and Mantle Using Self-Descending, Radiation-Heated, Probes and Acoustic Emission Monitoring". Chapter 7. In: Nuclear Waste Research: Siting, Technology and Treatment, ISBN 978-1-60456-184-5, Editor: Arnold P. Lattefer, Nova Science Publishers, Inc. 2008
  28. ^ University of California – Davis (2009-06-15). Super-computer Provides First Glimpse Of Earth's Early Magma Interior. ScienceDaily. Retrieved on 2009-06-16.

March 03, 2023
upper, mantle, earth, upper, mantle, earth, very, thick, layer, rock, inside, planet, which, begins, just, beneath, crust, about, under, oceans, about, under, continents, ends, lower, mantle, temperatures, range, from, approximately, upper, boundary, with, cru. The upper mantle of Earth is a very thick layer of rock inside the planet which begins just beneath the crust at about 10 km 6 2 mi under the oceans and about 35 km 22 mi under the continents and ends at the top of the lower mantle at 670 km 420 mi Temperatures range from approximately 500 K 227 C 440 F at the upper boundary with the crust to approximately 1 200 K 930 C 1 700 F at the boundary with the lower mantle Upper mantle material that has come up onto the surface comprises about 55 olivine 35 pyroxene and 5 to 10 of calcium oxide and aluminum oxide minerals such as plagioclase spinel or garnet depending upon depth Contents 1 Seismic structure 1 1 Lehmann discontinuity 1 2 Transition zone 1 3 410 km discontinuity 1 4 670 km discontinuity 1 5 Other discontinuities 2 Temperature and pressure 3 Movement 4 Mineral composition 5 Chemical composition 6 Exploration 7 ReferencesSeismic structure Edit 1 continental crust 2 oceanic crust 3 upper mantle 4 lower mantle 5 6 core A crust mantle boundary Mohorovicic discontinuity The density profile through Earth is determined by the velocity of seismic waves Density increases progressively in each layer largely due to compression of the rock at increased depths Abrupt changes in density occur where the material composition changes 1 The upper mantle begins just beneath the crust and ends at the top of the lower mantle The upper mantle causes the tectonic plates to move Crust and mantle are distinguished by composition while the lithosphere and asthenosphere are defined by a change in mechanical properties 2 The top of the mantle is defined by a sudden increase in the speed of seismic waves which Andrija Mohorovicic first noted in 1909 this boundary is now referred to as the Mohorovicic discontinuity or Moho 3 The Moho defines the base of the crust and varies from 10 km 6 2 mi to 70 km 43 mi below the surface of the Earth Oceanic crust is thinner than continental crust and is generally less than 10 km 6 2 mi thick Continental crust is about 35 km 22 mi thick but the large crustal root under the Tibetan Plateau is approximately 70 km 43 mi thick 4 The thickness of the upper mantle is about 640 km 400 mi The entire mantle is about 2 900 km 1 800 mi thick which means the upper mantle is only about 20 of the total mantle thickness 4 Cross section of the Earth showing the paths of earthquake waves The paths curve because the different rock types found at different depths change the waves speed S waves do not travel through the core The boundary between the upper and lower mantle is a 670 km 420 mi discontinuity 2 Earthquakes at shallow depths result from strike slip faulting however below about 50 km 31 mi the hot high pressure conditions inhibit further seismicity The mantle is viscous and incapable of faulting However in subduction zones earthquakes are observed down to 670 km 420 mi 1 Lehmann discontinuity Edit The Lehmann discontinuity is an abrupt increase of P wave and S wave velocities at a depth of 220 km 140 mi 5 Note that this is a different Lehmann discontinuity than the one between the Earth s inner and outer cores labeled in the image on the right Transition zone Edit The transition zone is located between the upper mantle and the lower mantle between a depth of 410 km 250 mi and 670 km 420 mi This is thought to occur as a result of the rearrangement of grains in olivine to form a denser crystal structure as a result of the increase in pressure with increasing depth 6 Below a depth of 670 km 420 mi due to pressure changes ringwoodite minerals change into two new denser phases bridgmanite and periclase This can be seen using body waves from earthquakes which are converted reflected or refracted at the boundary and predicted from mineral physics as the phase changes are temperature and density dependent and hence depth dependent 6 410 km discontinuity Edit A single peak is seen in all seismological data at 410 km 250 mi which is predicted by the single transition from a to b Mg2SiO4 olivine to wadsleyite From the Clapeyron slope this discontinuity is expected to be shallower in cold regions such as subducting slabs and deeper in warmer regions such as mantle plumes 6 670 km discontinuity Edit This is the most complex discontinuity and marks the boundary between the upper and lower mantle It appears in PP precursors a wave that reflects off the discontinuity once only in certain regions but is always apparent in SS precursors 6 It is seen as single and double reflections in receiver functions for P to S conversions over a broad range of depths 640 720 km or 397 447 mi The Clapeyron slope predicts a deeper discontinuity in colder regions and a shallower discontinuity in hotter regions 6 This discontinuity is generally linked to the transition from ringwoodite to bridgmanite and periclase 7 This is thermodynamically an endothermic reaction and creates a viscosity jump Both characteristics cause this phase transition to playing an important role in geodynamical models 8 Other discontinuities Edit There is another major phase transition predicted at 520 km 320 mi for the transition of olivine b to g and garnet in the pyrolite mantle 9 This one has only sporadically been observed in seismological data 10 Other non global phase transitions have been suggested at a range of depths 6 11 Temperature and pressure EditTemperatures range from approximately 500 K 227 C 440 F at the upper boundary with the crust to approximately 4 200 K 3 930 C 7 100 F at the core mantle boundary 12 The highest temperature of the upper mantle is 1 200 K 930 C 1 700 F 13 Although the high temperature far exceeds the melting points of the mantle rocks at the surface the mantle is almost exclusively solid 14 The enormous lithostatic pressure exerted on the mantle prevents melting because the temperature at which melting begins the solidus increases with pressure 15 Pressure increases as depth increases since the material beneath has to support the weight of all the material above it The entire mantle is thought to deform like a fluid on long timescales with permanent plastic deformation The highest pressure of the upper mantle is 24 0 GPa 237 000 atm 13 compared to the bottom of the mantle which is 136 GPa 1 340 000 atm 12 16 Estimates for the viscosity of the upper mantle range between 1019 and 1024 Pa s depending on depth 17 temperature composition state of stress and numerous other factors 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 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 17 Movement EditBecause of the temperature difference between the Earth s surface and outer core and the ability of the crystalline rocks at high pressure and temperature to undergo slow creeping viscous like deformation over millions of years there is a convective material circulation in the mantle 3 Hot material upwells while cooler and heavier material sinks downward Downward motion of material occurs at convergent plate boundaries called subduction zones Locations on the surface that lie over plumes are predicted to have high elevation because of the buoyancy of the hotter less dense plume beneath and to exhibit hot spot volcanism Mineral composition EditThe seismic data is not sufficient to determine the composition of the mantle Observations of rocks exposed on the surface and other evidence reveal that the upper mantle is mafic minerals olivine and pyroxene and it has a density of about 3 33 g cm3 0 120 lb cu in 1 Upper mantle material that has come up onto the surface comprises about 55 olivine and 35 pyroxene and 5 to 10 of calcium oxide and aluminum oxide 1 The upper mantle is dominantly peridotite composed primarily of variable proportions of the minerals olivine clinopyroxene orthopyroxene and an aluminous phase 1 The aluminous phase is plagioclase in the uppermost mantle then spinel and then garnet below about 100 kilometres 62 mi 1 Gradually through the upper mantle pyroxenes become less stable and transform into majoritic garnet Experiments on olivines and pyroxenes show that these minerals change the structure as pressure increases at greater depth which explains why the density curves are not perfectly smooth When there is a conversion to a more dense mineral structure the seismic velocity rises abruptly and creates a discontinuity 1 At the top of the transition zone olivine undergoes isochemical phase transitions to wadsleyite and ringwoodite Unlike nominally anhydrous olivine these high pressure olivine polymorphs have a large capacity to store water in their crystal structure This has led to the hypothesis that the transition zone may host a large quantity of water 18 In Earth s interior olivine occurs in the upper mantle at depths less than 410 kilometres 250 mi and ringwoodite is inferred within the transition zone from about 520 to 670 kilometres 320 to 420 mi depth Seismic activity discontinuities at about 410 kilometres 250 mi 520 kilometres 320 mi and 670 kilometres 420 mi depth have been attributed to phase changes involving olivine and its polymorphs At the base of the transition zone ringwoodite decomposes into bridgmanite formerly called magnesium silicate perovskite and ferropericlase Garnet also becomes unstable at or slightly below the base of the transition zone Kimberlites explode from the earth s interior and sometimes carry rock fragments Some of these xenolithic fragments are diamonds that can only come from the higher pressures below the crust The rocks that come with this are ultramafic nodules and peridotite 1 Chemical composition EditThe composition seems to be very similar to the crust One difference is that rocks and minerals of the mantle tend to have more magnesium and less silicon and aluminum than the crust The first four most abundant elements in the upper mantle are oxygen magnesium silicon and iron Composition of the Earth s upper mantle depleted MORB 19 20 Compound Mass percentSiO2 44 71MgO 38 73FeO 8 18Al2O3 3 98CaO 3 17Cr2O3 0 57NiO 0 24MnO 0 13Na2O 0 13TiO2 0 13P2O5 0 019K2O 0 006Exploration Edit Chikyu drilling ship Exploration of the mantle is generally conducted at the seabed rather than on land because of the oceanic crust s relative thinness as compared to the significantly thicker continental crust The first attempt at mantle exploration known as Project Mohole was abandoned in 1966 after repeated failures and cost overruns The deepest penetration was approximately 180 m 590 ft In 2005 an oceanic borehole reached 1 416 metres 4 646 ft below the seafloor from the ocean drilling vessel JOIDES Resolution On 5 March 2007 a team of scientists on board the RRS James Cook embarked on a voyage to an area of the Atlantic seafloor where the mantle lies exposed without any crust covering midway between the Cape Verde Islands and the Caribbean Sea The exposed site lies approximately 3 kilometres 1 9 mi beneath the ocean surface and covers thousands of square kilometers 21 22 23 The Chikyu Hakken mission attempted to use the Japanese vessel Chikyu to drill up to 7 000 m 23 000 ft below the seabed On 27 April 2012 Chikyu drilled to a depth of 7 740 metres 25 390 ft below sea level setting a new world record for deep sea drilling This record has since been surpassed by the ill fated Deepwater Horizon mobile offshore drilling unit operating on the Tiber prospect in the Mississippi Canyon Field United States Gulf of Mexico when it achieved a world record for total length for a vertical drilling string of 10 062 m 33 011 ft 24 The previous record was held by the U S vessel Glomar Challenger which in 1978 drilled to 7 049 5 meters 23 130 feet below sea level in the Mariana Trench 25 On 6 September 2012 Scientific deep sea drilling vessel Chikyu set a new world record by drilling down and obtaining rock samples from deeper than 2 111 metres 6 926 ft below the seafloor off the Shimokita Peninsula of Japan in the northwest Pacific Ocean A novel method of exploring the uppermost few hundred kilometers of the Earth was proposed in 2005 consisting of a small dense heat generating probe that melts its way down through the crust and mantle while its position and progress are tracked by acoustic signals generated in the rocks 26 The probe consists of an outer sphere of tungsten about 1 metre 3 ft 3 in in diameter with a cobalt 60 interior acting as a radioactive heat source This should take half a year to reach the oceanic Moho 27 Exploration can also be aided through computer simulations of the evolution of the mantle In 2009 a supercomputer application provided new insight into the distribution of mineral deposits especially isotopes of iron from when the mantle developed 4 5 billion years ago 28 References Edit a b c d e f g h Langmuir Charles H Broecker Wally 2012 07 22 How to Build a Habitable Planet The Story of Earth from the Big Bang to Humankind pp 179 183 ISBN 9780691140063 a b Rothery David A Gilmour Iain Sephton Mark A March 2018 An Introduction to Astrobiology p 56 ISBN 9781108430838 a b Alden Andrew 2007 Today s Mantle a guided tour About com Retrieved 2007 12 25 a b Istria on the Internet Prominent Istrians Andrija Mohorovicic 2007 Retrieved 2007 12 25 William Lowrie 1997 Fundamentals of geophysics Cambridge University Press p 158 ISBN 0 521 46728 4 a b c d e f Fowler C M R Fowler Connie May 2005 The Solid Earth An Introduction to Global Geophysics ISBN 978 0521893077 Ito E Takahashi E 1989 Postspinel transformations in the system Mg2SiO4 Fe2SiO4 and some geophysical implications Journal of Geophysical Research Solid Earth 94 B8 10637 10646 Bibcode 1989JGR 9410637I doi 10 1029 jb094ib08p10637 Fukao Y Obayashi M 2013 Subducted slabs stagnant above penetrating through and trapped below the 660 km discontinuity Journal of Geophysical Research Solid Earth 118 11 5920 5938 Bibcode 2013JGRB 118 5920F doi 10 1002 2013jb010466 S2CID 129872709 Deuss Arwen Woodhouse John 2001 10 12 Seismic Observations of Splitting of the Mid Transition Zone Discontinuity in Earth s Mantle Science 294 5541 354 357 Bibcode 2001Sci 294 354D doi 10 1126 science 1063524 ISSN 0036 8075 PMID 11598296 S2CID 28563140 Egorkin A V 1997 01 01 Evidence for 520 Km Discontinuity In Fuchs Karl ed Upper Mantle Heterogeneities from Active and Passive Seismology NATO ASI Series Springer Netherlands pp 51 61 doi 10 1007 978 94 015 8979 6 4 ISBN 9789048149667 Khan Amir Deschamps Frederic 2015 04 28 The Earth s Heterogeneous Mantle A Geophysical Geodynamical and Geochemical Perspective Springer ISBN 9783319156279 a b Lodders Katharina 1998 The planetary scientist s companion Fegley Bruce New York Oxford University Press ISBN 978 1423759836 OCLC 65171709 a b What Are Three Differences Between the Upper amp Lower Mantle Sciencing Retrieved 14 June 2019 Louie J 1996 Earth s Interior University of Nevada Reno Archived from the original on 2011 07 20 Retrieved 2007 12 24 Turcotte DL Schubert G 2002 4 Geodynamics 2nd ed Cambridge England UK Cambridge University Press pp 136 7 ISBN 978 0 521 66624 4 Burns Roger George 1993 Mineralogical Applications of Crystal Field Theory Cambridge University Press p 354 ISBN 978 0 521 43077 7 Retrieved 2007 12 26 a b Walzer Uwe Mantle Viscosity and the Thickness of the Convective Downwellings Archived from the original on 2007 06 11 Bercovici David Karato Shun ichiro September 2003 Whole mantle convection and the transition zone water filter Nature 425 6953 39 44 Bibcode 2003Natur 425 39B doi 10 1038 nature01918 ISSN 0028 0836 PMID 12955133 S2CID 4428456 Workman Rhea K Hart Stanley R February 2005 Major and trace element composition of the depleted MORB mantle DMM Earth and Planetary Science Letters 231 1 2 53 72 Bibcode 2005E amp PSL 231 53W doi 10 1016 j epsl 2004 12 005 ISSN 0012 821X Anderson D L 2007 New Theory of the Earth Cambridge University Press p 301 ISBN 9780521849593 Than Ker 2007 03 01 Scientists to study gash on Atlantic seafloor NBC News Retrieved 2008 03 16 A team of scientists will embark on a voyage next week to study an open wound on the Atlantic seafloor where the Earth s deep interior lies exposed without any crust covering Earth s Crust Missing In Mid Atlantic Science Daily 2007 03 02 Retrieved 2008 03 16 Cardiff University scientists will shortly set sail March 5 to investigate a startling discovery in the depths of the Atlantic Japan hopes to predict Big One with journey to center of Earth PhysOrg com 2005 12 15 Archived from the original on 2005 12 19 Retrieved 2008 03 16 An ambitious Japanese led project to dig deeper into the Earth s surface than ever before will be a breakthrough in detecting earthquakes including Tokyo s dreaded Big One officials said Thursday Explore Records Guinness World Records Archived from the original on 2011 10 17 Japan deep sea drilling probe sets world record The Kansas City Star Associated Press 28 April 2012 Archived from the original on 28 April 2012 Retrieved 28 April 2012 Ojovan M I Gibb F G F Poluektov P P Emets E P 2005 Probing of the interior layers of the Earth with self sinking capsules Atomic Energy 99 556 562 Ojovan M I Gibb F G F Exploring the Earth s Crust and Mantle Using Self Descending Radiation Heated Probes and Acoustic Emission Monitoring Chapter 7 In Nuclear Waste Research Siting Technology and Treatment ISBN 978 1 60456 184 5 Editor Arnold P Lattefer Nova Science Publishers Inc 2008 University of California Davis 2009 06 15 Super computer Provides First Glimpse Of Earth s Early Magma Interior ScienceDaily Retrieved on 2009 06 16 Retrieved from https en wikipedia org w index php title Upper mantle Earth amp oldid 1130144107, wikipedia, wiki, book, books, library,

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