Closure temperatures of intracrystalline ordering in anatectic and metamorphic hercynite, fe2+al2o4

Barbara Lavina, Bernardo Cesare, Antonio M. Alvarez-Valero, Hinako Uchida, Robert T. Downs, Anna Koneva, Przemyslaw Dera

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13 Scopus citations


The closure temperature, Tc, of the intracrystalline ordering of Mg-hercynite is estimated with a comparative ciystal-chemical approach. The single crystals were selected from two distinct geological environments that represent extremely different cooling rates. The fast cooled setting refers to anatectic metapelitic enclaves that occur in the high-K calc-alkaline lavas of the Neogene Volcanic Province of SE Spain. The slow cooled setting refers to metabauxite from the Anga metamorphic complex. Lake Baikal. Parameters sensitive to Tc include the oxygen fractional coordinate (u) and the inversion parameter (i). Experimental equilibration data on the spinel and hercynite end-members and on their solid solution are fitted to equations where T c is given as a function of the hercynite content (Hc) of the solid solution and of u or i. The unavoidable simplifications made in this empirical approach are discussed. A reasonable value for Tc, ~400 °C, was obtained for the slow cooled metamorphic hercynite from the oxygen fractional coordinates. In contrast, an unreasonably high value of Tc, ~600 °C, was obtained from the inversion parameters. In the case of the fast cooled anatectic samples, Tccalculated from the two structural parameters are comparable; the five crystals show a range in the calculated values for Tc over ~250 °C, from ~700 to ~950 °C, which is reasonable considering the known diversity of cooling rates exhibited by their volcanic host-rocks.

Original languageEnglish (US)
Pages (from-to)657-665
Number of pages9
JournalAmerican Mineralogist
Issue number5-6
StatePublished - 2009


  • Closure temperature
  • Hercynite
  • Spinel

ASJC Scopus subject areas

  • Geophysics
  • Geochemistry and Petrology


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