Open Access Articles- Top Results for Mohorovi%C4%8Di%C4%87 discontinuity

Mohorovičić discontinuity

World map showing the depth of the Moho.

The Mohorovičić discontinuity (Croatian pronunciation: [moxorôʋiːt͡ʃit͡ɕ]),[1] usually referred to as the Moho, is the boundary between the Earth's crust and the mantle. Named after the pioneering Croatian seismologist Andrija Mohorovičić, the Moho separates both the oceanic crust and continental crust from underlying mantle. The Moho lies almost entirely within the lithosphere; only beneath mid-ocean ridges does it define the lithosphere–asthenosphere boundary. The Mohorovičić discontinuity was first identified in 1909 by Mohorovičić, when he observed that seismograms from shallow-focus earthquakes had two sets of P-waves and S-waves, one that followed a direct path near the Earth's surface and the other refracted by a high-velocity medium.[2]

The Mohorovičić discontinuity is Script error: No such module "convert". below the ocean floor, and Script error: No such module "convert"., with an average of Script error: No such module "convert"., beneath typical continents.[3]


Earth cross-section showing location of the Mohorovičić discontinuity (labelled as 2)
File:Refraction of P-wave.PNG
Two paths of a P-wave, one direct and one refracted as it crosses the Moho.[2]
File:Gros Morne moho.jpg
Ordovician ophiolite in Gros Morne National Park, Newfoundland. This rock which formed the Ordovician Moho is exposed on the surface.

Immediately above the Moho, the velocities of primary seismic waves (P-waves) are consistent with those through basalt (6.7–7.2 km/s), and below they are similar to those through peridotite or dunite (7.6–8.6 km/s).[4] That suggests the Moho marks a change of composition, but the interface appears to be too even for any believable sorting mechanism within the Earth. Near-surface observations suggest such sorting produces an irregular surface.[5]

The Moho is characterized by a transition zone of up to 500 m thick.[6] Ancient Moho zones are exposed above-ground in numerous ophiolites around the world.


During the late 1950s and early 1960s the executive committee of the U.S. National Science Foundation funded drilling a hole through the ocean floor to reach this boundary. However the operation, named Project Mohole, never received sufficient support and was mismanaged[citation needed]; the United States Congress canceled it in 1967. Soviet scientists at the Kola Institute pursued the goal simultaneously; after 15 years they reached a depth of Script error: No such module "convert"., the world's deepest hole, before abandoning their attempt in 1989.[7]

Reaching the discontinuity remains an important scientific objective. One proposal considers a rock-melting radionuclide-powered capsule with a heavy tungsten needle that can propel itself down to the Moho discontinuity and explore Earth's interior near it and in the upper mantle.[8] The Japanese project Chikyu Hakken ("Earth Discovery") also aims to explore this general area with the drilling ship, Chikyū, built for the Integrated Ocean Drilling Program (IODP).

See also


  1. ^ Mangold, Max (2005). Aussprachewörterbuch (in German) (6th ed.). Mannheim: Dudenverlag. p. 559. ISBN 9783411040667. 
  2. ^ a b Andrew McLeish (1992). Geological science (2nd ed.). Thomas Nelson & Sons. p. 122. ISBN 0-17-448221-3. 
  3. ^ James Stewart Monroe; Reed Wicander (2008). The changing Earth: exploring geology and evolution (5th ed.). Cengage Learning. p. 216. ISBN 0-495-55480-4. 
  4. ^ RB Cathcart & MM Ćirković (2006). Viorel Badescu; Richard Brook Cathcart & Roelof D. Schuiling, eds. Macro-engineering: a challenge for the future. Springer. p. 169. ISBN 1-4020-3739-2. 
  5. ^ Benjamin Franklin Howell (1990). An introduction to seismological research: history and development. Cambridge University Press. p. 77 ff. ISBN 0-521-38571-7. 
  6. ^ D.P. McKenzie - The Mohorovičić Discontinuity
  7. ^ "How the Soviets Drilled the Deepest Hole in the World". Wired. 2008-08-25. Retrieved 2008-08-26. 
  8. ^ Ozhovan, M.; F. Gibb; P. Poluektov & E. Emets (August 2005). "Probing of the Interior Layers of the Earth with Self-Sinking Capsules". Atomic Energy 99 (2): 556–562. doi:10.1007/s10512-005-0246-y. 


External links