Minimum speed limit for ocean ridge magmatism from 210Pb–226Ra–230Th disequilibria

Although 70 per cent of global crustal magmatism occurs at mid-ocean ridges 1 —where the heat budget controls crustal structure, hydrothermal activity and a vibrant biosphere—the tempo of magmatic inputs in these regions remains poorly understood. Such timescales can be assessed, however, with natur...

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Bibliographic Details
Published in:Nature (London) 2005-09, Vol.437 (7058), p.534-538
Main Authors: Rubin, K. H., van der Zander, I., Smith, M. C., Bergmanis, E. C.
Format: Article
Language:English
Subjects:
Crystalline rocks
Earth sciences
Earth, ocean, space
Exact sciences and technology
Humanities and Social Sciences
Igneous and metamorphic rocks petrology, volcanic processes, magmas
Isotope geochemistry
Isotope geochemistry. Geochronology
letter
multidisciplinary
Science
Science (multidisciplinary)
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Summary:Although 70 per cent of global crustal magmatism occurs at mid-ocean ridges 1 —where the heat budget controls crustal structure, hydrothermal activity and a vibrant biosphere—the tempo of magmatic inputs in these regions remains poorly understood. Such timescales can be assessed, however, with natural radioactive-decay-chain nuclides, because chemical disruption to secular equilibrium systems initiates parent–daughter disequilibria, which re-equilibrate by the shorter half-life in a pair. Here we use 210 Pb– 226 Ra– 230 Th radioactive disequilibria and other geochemical attributes in oceanic basalts less than 20 years old to infer that melts of the Earth's mantle can be transported, accumulated and erupted in a few decades. This implies that magmatic conditions can fluctuate rapidly at ridge volcanoes. 210 Pb deficits of up to 15 per cent relative to 226 Ra occur in normal mid-ocean ridge basalts, with the largest deficits in the most magnesium-rich lavas. The 22-year half-life of 210 Pb requires very recent fractionation of these two uranium-series nuclides. Relationships between 210 Pb-deficits, ( 226 Ra/ 230 Th) activity ratios and compatible trace-element ratios preclude crustal-magma differentiation or daughter-isotope degassing as the main causes for the signal. A mantle-melting model 2 can simulate observed disequilibria but preservation requires a subsequent mechanism to transport melt rapidly. The likelihood of magmatic disequilibria occurring before melt enters shallow crustal magma bodies also limits differentiation and heat replenishment timescales to decades at the localities studied.
ISSN:0028-0836
1476-4687
DOI:10.1038/nature03993