LITHOSPHERE

Lithosphere

From Wikipedia, the free encyclopedia

A lithosphere (Ancient Greek: λίθος [lithos] for "rocky", and σφαῖρα [sphaira] for "sphere") is the rigid,^[1] outermost shell of a rocky planet, and can be identified on the basis of its mechanical properties. On Earth, it comprises thecrust and the portion of the upper mantle that behaves elastically on time scales of thousands of years or greater. The outermost shell of a rocky planet is, the crust, defined on the basis of its chemistry and mineralogy.

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The tectonic plates of the lithosphere on Earth

Earth's lithosphere[edit]

In the Earth, the lithosphere includes the crust and the uppermost mantle, which constitute the hard and rigid outer layer of the Earth. The lithosphere is underlain by the asthenosphere, the weaker, hotter, and deeper part of the upper mantle. The boundary between the lithosphere and the underlying asthenosphere is defined by a difference in response to stress: the lithosphere remains rigid for very long periods of geologic time in which it deforms elastically and through brittle failure, while the asthenosphere deforms viscously and accommodates strain through plastic deformation. The lithosphere is broken into tectonic plates. The uppermost part of the lithosphere that chemically reacts to the atmosphere, hydrosphere and biosphere through the soil forming process is called thepedosphere.

The concept of the lithosphere as Earth’s strong outer layer was developed by Joseph Barrell, who wrote a series of papers introducing the concept.^[2][3][4][5] The concept was based on the presence of significant gravity anomalies over continental crust, from which he inferred that there must exist a strong upper layer (which he called the lithosphere) above a weaker layer which could flow (which he called the asthenosphere). These ideas were expanded by Harvard geologist Reginald Aldworth Daly in 1940 with his seminal work "Strength and Structure of the Earth"^[6] and have been broadly accepted by geologists and geophysicists. Although these ideas about lithosphere and asthenosphere were developed long before plate tectonic theory was articulated in the 1960s, the concepts that a strong lithosphere exists and that this rests on a weak asthenosphere are essential to that theory.

There are two types of lithosphere:

- Oceanic lithosphere, which is associated with oceanic crust and exists in the ocean basins (mean density of about 2.9 grams per cubic centimeter)
- Continental lithosphere, which is associated with continental crust (mean density of about 2.7 grams per cubic centimeter)

The thickness of the lithosphere is considered to be the depth to the isotherm associated with the transition between brittle and viscous behavior.^[7] The temperature at which olivine begins to deform viscously (~1000 °C) is often used to set this isotherm because olivine is generally the weakest mineral in the upper mantle. Oceanic lithosphere is typically about 50–140 km thick ^[8](but beneath the mid-ocean ridges is no thicker than the crust), while continental lithosphere has a range in thickness from about 40 km to perhaps 280 km;^[8] the upper ~30 to ~50 km of typical continental lithosphere is crust. The mantle part of the lithosphere consists largely of peridotite. The crust is distinguished from the upper mantle by the change in chemical composition that takes place at the Moho discontinuity.

Oceanic lithosphere[edit]

Oceanic lithosphere consists mainly of mafic crust and ultramafic mantle (peridotite) and is denser than continental lithosphere, for which the mantle is associated with crust made of felsic rocks. Oceanic lithosphere thickens as it ages and moves away from the mid-ocean ridge. This thickening occurs by conductive cooling, which converts hot asthenosphere into lithospheric mantle and causes the oceanic lithosphere to become increasingly thick and dense with age. The thickness of the mantle part of the oceanic lithosphere can be approximated as a thermal boundary layer that thickens as the square root of time.

Here,

Earth cutaway from core to crust, the lithosphere comprising the crust and lithospheric mantle (detail not to scale)

is the thickness of the oceanic mantle lithosphere, is the thermal diffusivity (approximately 10⁻⁶ m²/s) for silicate rocks, and is the age of the given part of the lithosphere. The age is often equal to L/V, where L is the distance from the spreading centre of mid-oceanic ridge, and V is velocity of the lithospheric plate.

Oceanic lithosphere is less dense than asthenosphere for a few tens of millions of years but after this becomes increasingly denser than asthenosphere. This is because the chemically differentiated oceanic crust is lighter than asthenosphere, but thermal contraction of the mantle lithosphere makes it more dense than the asthenosphere. The gravitational instability of mature oceanic lithosphere has the effect that at subduction zones, oceanic lithosphere invariably sinks underneath the overriding lithosphere, which can be oceanic or continental. New oceanic lithosphere is constantly being produced at mid-ocean ridges and is recycled back to the mantle at subduction zones. As a result, oceanic lithosphere is much younger than continental lithosphere: the oldest oceanic lithosphere is about 170 million years old, while parts of the continental lithosphere are billions of years old. The oldest parts of continental lithosphere underlie cratons, and the mantle lithosphere there is thicker and less dense than typical; the relatively low density of such mantle "roots of cratons" helps to stabilize these regions.^[9][10]

Subducted lithosphere[edit]

Geophysical studies in the early 21st century posit that large pieces of the lithosphere have been subducted into the mantle as deep as 2900 km to near the core-mantle boundary,^[11] while others "float" in the upper mantle,^[12][13] while some stick down into the mantle as far as 400 km but remain "attached" to the continental plate above,^[10] similar to the extent of the "tectosphere" proposed by Jordan in 1988.^[14]

Mantle xenoliths[edit]

Geoscientists can directly study the nature of the subcontinental mantle by examining mantle xenoliths^[15] brought up inkimberlite, lamproite, and other volcanic pipes. The histories of these xenoliths have been investigated by many methods, including analyses of abundances of isotopes of osmium and rhenium. Such studies have confirmed that mantle lithospheres below some cratons have persisted for periods in excess of 3 billion years, despite the mantle flow that accompanies plate tectonics.^[16]

Litosfer

Dari Wikipedia bahasa Indonesia, ensiklopedia bebas

http://id.wikipedia.org/wiki/Litosfer

Litosfer adalah kulit terluar dari planet berbatu. Litosfer berasal dari kata Yunani, lithos (λίθος) yang berarti berbatu, dan sphere (σφαῖρα) yang berarti padat. Litosfer berasal dari kata lithos artinya batuan, dan sphere artinya lapisan. Secara harfiah litosfer adalah lapisan Bumi yang paling luar atau biasa disebut dengan kulit Bumi. Pada lapisan ini pada umumnya terjadi dari senyawa kimia yang kaya akan Si0₂, itulah sebabnya lapisan litosfer sering dinamakan lapisan silikat dan memiliki ketebalan rata-rata 30 km yang terdiri atas dua bagian, yaitu Litosfer atas (merupakan daratan dengan kira-kira 35% atau 1/3 bagian) dan Litosfer bawah (merupakan lautan dengan kira-kira 65% atau 2/3 bagian).

Litosfer Bumi meliputi kerak dan bagian teratas dari mantel Bumi yang mengakibatkan kerasnya lapisan terluar dari planet Bumi. Litosfer ditopang oleh astenosfer, yang merupakan bagian yang lebih lemah, lebih panas, dan lebih dalam dari mantel. Batas antara litosfer dan astenosfer dibedakan dalam hal responnya terhadap tegangan: litosfer tetap padat dalam jangka waktu geologis yang relatif lama dan berubah secara elastis karena retakan-retakan, sednagkan astenosfer berubah seperti cairan kental.

Litosfer terpecah menjadi beberapa lempeng tektonik yang mengakibatkan terjadinya gerak benua akibat konveksi yang terjadi dalam astenosfer.

Konsep litosfer sebagai lapisan terkuat dari lapisan terluar Bumi dikembangkan oleh Barrel pada tahun 1914, yang menulis serangkaian paper untuk mendukung konsep itu. konsep yang berdasarkan pada keberadaan anomali gravitasi yang signifikan di atas kerak benua, yang lalu ia memperkirakan keberadaan lapisan kuat (yang ia sebut litosfer) di atas lapisan lemah yang dapat mengalir secara konveksi (yang ia sebut astenosfer). Ide ini lalu dikembangkan oleh Daly pada tahun 1940, dan telah diterima secara luas oleh ahli geologi dan geofisika. Meski teori tentang litosfer dan astenosfer berkembang sebelum teori lempeng tektonik dikembangkan pada tahun 1960, konsep mengenai keberadaan lapisan kuat (litosfer) dan lapisan lemah (astenosfer) tetap menjadi bagian penting dari teori tersebut.

Terdapat dua tipe litosfer

- Litosfer samudra, yang berhubungan dengan kerak samudra dan berada di dasar samdura
- Litosfer benua, yang berhubungan dengan kerak benua

Litosfer samudra memiliki ketebalan 50-100 km, sementara litosfer benua memiliki kedalaman 40-200 km. Kerak benua dibedakan dengan lapisan mantel atas karena keberadaan lapisan Mohorovicic

Belum Diperiksa

Daftar isi [sembunyikan]

Material Pembentuk Litosfer[sunting | sunting sumber]

Litosfer tersusun atas tiga macam material utama dengan bahan dasar pembentukannya adalah Magma dengan berbagai proses yang berbeda-beda. Berikut merupakan material batuan penyusun litosfer,

Batuan Beku (Igneous Rock)[sunting | sunting sumber]

Batuan beku adalah batuan yang terbentuk dari magma pijar yang membeku menjadi padat, dengan sekitar 80% material batuan yang menyusun batuan kerak Bumi adalah batuan beku. Berdasarkan tempat terbentuknya magma beku. batuan beku dibagi menjadi tiga macam,

- Batuan Beku Dalam (Plutonik/Abisik)[sunting | sunting sumber]

Batuan beku dalam terjadi dari pembekuan magma yang berlangsung perlahan-lahan ketika masih berada jauh di dalam kulit Bumi. Contoh batuan beku dalam adalah granit, diorit, dan gabbro.

- Batuan Beku Gang/Korok (hypabisal)[sunting | sunting sumber]

Batuan beku korok terjadi dari magma yang membeku di lorong antara dapur magma dan permukaan Bumi. Magma yang meresap di antara lapisan-lapisan litosfer mengalami proses pembekuan yang berlangsung lebih cepat, sehingga kristal mineral yang terbentuk tidak semua besar. Campuran kristal mineral yang besarnya tidak sama merupakan ciri batuan beku korok.

- Batuan Beku Luar(vulkanik)[sunting | sunting sumber]

Batuan beku luar terjadi dari magma yang keluar dari dapur magma membeku di permukaan Bumi (seperti magma hasil letusan gunung berapi). Contoh batuan beku luar adalah : basalt, diorit, andesit, obsidin, scoria, batuan apung (pumice).

Batuan Sedimen (Sedimentary Rock)[sunting | sunting sumber]

Batuan Sedimen merupakan batuan mineral yang telah terbentuk dipermukaan Bumi yang mengalami pelapukan. Bagian - bagian yang lepas dari hasil pelapukan tersebut terlepas dan ditansportasikan oleh aliran air, angin, maupun oleh gletser yang kemudian terendapkan atau tersedimentasi dan terjadilah proses diagenesis yang menyebabkan endapan tersebut mengeras dan menjadi bantuan sedimen. Batuan Sedimen berdasar proses pembentukannya terdiri atas,

1. Batuan Sedimen Klastik
2. Batuan Sedimen Kimiawi
3. Batuan Sedimen Organik

Berdasar tenaga yang mengangkutnya Batuan Sedimen terdiri atas,

1. Batuan Sedimen Aeris atau Aeolis
2. Batuan Sedimen Glasial
3. Batuan Sedimen Aquatis
4. Batuan Sedimen Marine

Batuan Malihan (Metamorf)[sunting | sunting sumber]

Batuan Malihan terbentuk karena terjadinya penambahan suhu atau penambahan tekanan yang tinggi dan terjadi secara bersamaan pada batuan sedimen.

Struktur Lapisan Kerak Bumi[sunting | sunting sumber]

Di dalam litosfer terdapat lebih dari 2000 mineral dan hanya 20 mineral yang terdapat dalam batuan. Mineral pembentuk batuan yang penting, yaitu Kuarsa (Si0₂), Feldspar, Piroksen, Mika Putih (K-Al-Silikat), Biotit atau Mika Cokelat (K-Fe-Al-Silikat), Amphibol, Khlorit, Kalsit (CaC0₃), Dolomit (CaMgCO_T3), Olivin (Mg, Fe), Bijih Besi Hematit (Fe₂O₃), Magnetik (Fe₃O₂), dan Limonit (Fe₃OH₂O). Selain itu, litosfer juga terdiri atas dua bagian, yaitu lapisan Sial dan lapisan Sima. Lapisan Sial yaitu lapisan kulit Bumi yang tersusun atas logam silisium dan alumunium, senyawanya dalam bentuk SiO₂ dan Al₂O₃. Pada lapisan sial (silisium dan alumunium) ini antara lain terdapat batuan sedimen, granit, andesit, jenis-jenis batuan metamorf, dan batuan lain yang terdapat di daratan benua. Lapisan Sima (silisium magnesium) yaitu lapisan kulit Bumi yang tersusun oleh logam silisium dan magnesium dalam bentuk senyawa SiO₂dan MgO lapisan ini mempunyai berat jenis yang lebih besar daripada lapisan sial karena mengandung besi dan magnesium yaitu mineral ferro magnesium dan batuan basalt. Batuan pembentuk kulit Bumi selalu mengalami siklus atau daur, yaitu batuan mengalami perubahan wujud dari magma, batuan beku, batuan sedimen, batuan malihan, dan kembali lagi menjadi magma.

Referensi[sunting | sunting sumber]

- Geologi (J.A. Katili). Bandung: Pertjetakan Kilatmadju, 1979
- Barrel J. 1914. The Strength of the Earth's Crust. Journal of Geology
- Daly R. 1940. Strength and Structure of the Earth. New York: Prentice Hall

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