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Clays and Clay Minerals

, Volume 42, Issue 5, pp 572–575 | Cite as

Oxygen Isotopic Constraints on the Origin of Nodular Silica-Apatite from the Har Peres Pyroclastics, Golan Heights, Israel

  • C. Mizota
  • N. Yoshida
Article

Abstract

Oxygen isotope composition of three types of unique nodules which consist of amorphous silica-apatite, cristobalite-apatite and tridymite-apatite associations interspersed amidst basaltic pyroclastics from the Har Peres volcano, Golan Heights, Israel is reported. Unusual isotopic temperature (75°C estimated from oxygen isotope fractionation between cristobalite (δ18O = +25.5‰)-apatite (δ18O = +12.9‰) pair suggests that the nodule was not formed by present-day pedogenesis as has been previously proposed, but was a xenolith incorporated probably from the underlying siliceous phosphorites at a higher temperature. An observed negative oxygen isotopic fractionation (δ18O = −5.1‰) between tridymite (δ18O = +9.9‰) and associated apatite (δ18O = +15.0‰) is indicative of the nodular formation under disequilibrium conditions. A plausible mechanism of formation of the apatite (and calcite) associated with tridymite is an epitaxial overgrowth on template tridymite of magmatic origin under the current weathering regime. Oxygen isotopic evidence indicates a complicated origin for the nodules.

Key Words

Apatite Har Peres pyroclastics Oxygen isotope 

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Copyright information

© The Clay Minerals Society 1994

Authors and Affiliations

  • C. Mizota
    • 1
  • N. Yoshida
    • 2
  1. 1.Faculty of AgricultureIwate UniversityMoriokaJapan
  2. 2.Faculty of ScienceToyama UniversityToyamaJapan

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