Tracing the Indian Ocean Mantle Domain Through Time: Isotopic Results from Old West Indian, East Tethyan, and South Pacific Seafloor

doi:10.1093/petroj/39.7.1285

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Journal of Petrology | Volume 39 | Number 7 | Pages 1285-1306 | 1998
© Oxford University Press 1998

Tracing the Indian Ocean Mantle Domain Through Time: Isotopic Results from Old West Indian, East Tethyan, and South Pacific Seafloor

J. J. Mahoney¹^,*, R. Frei², M. L. G. Tejada¹, X. X. Mo³, P. T. Leat⁴ and T. F. NäGler⁵

¹ School of Ocean and Earth Science and Technology, University of Hawaii Honolulu, HI 96822, USA
² Geologisk Institut, Kobenhavns Universitet Kobenhavn, Denmark
³ Graduate School, China University of Geosciences Beijing 100 083, China
⁴ British Antarctic Survey High Cross, Madingley Road, Cambridge CB3 0ET, UK
⁵ Mineralogisch-Petrographisches Institut, UniversitäT Bern Erlachstr. 9A, CH-3012 Bern, Switzerland

Received June 9, 1997; Revised typescript accepted February 3, 1998

Abstract

The isotopic difference between modern Indian Ocean and Pacificor North Atlantic Ocean ridge mantle (e.g. variably lower ²⁰⁶Pb/²⁰⁴Pbfor a given ${varepsilon}$ _Nd and ²⁰⁸Pb/²⁰⁴Pb) could reflect processes thatoccurred within a few tens of millions of years preceding theinitial breakup of Gondwana. Alternatively, the Indian Oceanisotopic signature could be a much more ancient upper-mantlefeature inherited from the asthenosphere of the eastern TethyanOcean, which formerly occupied much of the present Indian Oceanregion. Age-corrected Nd, Pb, and Sr isotopic data for 46–150Ma seafloor lavas from sites in the western Indian Ocean andocean-ridge-type Tethyan ophiolites (Masirah, Yarlung–Zangpo)reveal the presence of both Indian-Ocean-type compositions andessentially Pacific–North Atlantic-type signatures. Incomparison, Jurassic South Pacific ridge basalts from AlexanderIsland, Antarctica, possess normal Pacific–North Atlantic-typeisotopic ratios. Despite the very sparse sampling of old seafloor,the age-corrected ${varepsilon}$ _Nd(t) values of the old Indian Ocean basaltscover a greater range than seen for the much more thoroughlysampled present-day spreading axes and islands within the IndianOcean (e.g. 18 ${varepsilon}$ _Nd units for basalts in the 60–80 Ma rangevs 15 ${varepsilon}$ _Nd units for 0–10 Ma ones). The implications ofthese results are that the upper mantle in the Indian Oceanregion is becoming increasingly well mixed through time, andthat the Indian Ocean mantle domain may not greatly pre-datethe age of earliest spreading in the Indian Ocean.

KEY WORDS: mantle geochemistry; old Indian Ocean; Tethyan crust

^* Corresponding author. Telephone: 808-956-8705. e-mail: jmahoney{at}soest.hawaii.edu

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