The electric Moho

Since Mohorovi i discovered a dramatic increase in compressional seismic velocity at a depth of 54 km beneath the Kulpa Valley in Croatia, the 'Moho' has become arguably the most important seismological horizon in Earth owing to its role in defining the crust-mantle boundary. It is now kno...

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Bibliographic Details
Published in:Nature (London) 2001-01, Vol.409 (6818), p.331-333
Main Authors: Jones, Alan G, Ferguson, Ian J
Format: Article
Language:English
Subjects:
Boundaries
Conduction
Cratons
Earth
Earth sciences
Earth, ocean, space
Electromagnetism
Exact sciences and technology
Geology
Geophysics: general, magnetic, electric and thermic methods and properties
Humanities and Social Sciences
Internal geophysics
letter
multidisciplinary
Oceans
Resistivity
Rocks
Science
Science (multidisciplinary)
Seismic phenomena
Seismology
Solid-earth geophysics, tectonophysics, gravimetry
Upper mantle
Valleys
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Summary:Since Mohorovi i discovered a dramatic increase in compressional seismic velocity at a depth of 54 km beneath the Kulpa Valley in Croatia, the 'Moho' has become arguably the most important seismological horizon in Earth owing to its role in defining the crust-mantle boundary. It is now known to be a ubiquitous feature of the Earth, being found beneath both the continents and the oceans, and is commonly assumed to separate lower-crustal mafic rocks from upper-mantle ultramafic rocks. Electromagnetic experiments conducted to date, however, have failed to detect a corresponding change in electrical conductivity at the base of the crust, although one might be expected on the basis of laboratory measurements. Here we report electromagnetic data from the Slave craton, northern Canada, which show a step-change in conductivity at Moho depths. Such resolution is possible because the Slave craton is highly anomalous, exhibiting a total crustal conductance of less than 1 Siemens-more than an order of magnitude smaller than other Archaean cratons. We also found that the conductivity of the uppermost continental mantle directly beneath the Moho is two orders of magnitude more conducting than laboratory studies on olivine would suggest, inferring that there must be a connected conducting phase.
ISSN:0028-0836
1476-4687
DOI:10.1038/35053053