• journal_title：American Mineralogist
• Contributor：Ferdinando Bosi ; Giovanna Agrosì ; Sergio Lucchesi ; Giovanni Melchiorre ; Eugenio Scandale
• Publisher：Mineralogical Society of America
• Date：2005-
• Format：text/html
• Language：en
• Identifier：10.2138/am.2005.1852
• journal_abbrev：American Mineralogist
• issn：0003-004X
• volume：90
• issue：10
• firstpage：1661
• section：Articles

The crystal chemistry of seven crystal fragments taken from differing regions of the same colorless to yellow-greenish tourmaline macro-crystal from pegmatite pockets in aplite veins (island of Elba, Italy) was studied with a multi-disciplinary (SREF, XRDT) and multi-analytical approach (EMPA, SIMS). EMPA and XRDT studies showed relationships between color and chemical zoning and crystal-growth evolution, indicating which fragments could be considered representative of the chemical evolution of the genetic micro-environment in which the crystal developed.

Results showed that the colorless fragment is an elbaite while the yellow-greenish crystal fragments are Mn²⁺-rich (up to 1.34 apfu) and belong to the alkali group and fluor subgroup. They are characterized by dehydroxylation and alkali-defect type substitutions that cooperate in reducing Li and increasing Mn contents. The Y site is populated by Al, Li, and Mn²⁺, and the Z site by Al and Mn²⁺ (up to 0.10 apfu). In contrast with data in the literature, Mn²⁺ populates both octahedral sites according to the order-disorder reaction: ^YMn + ^ZAl ↔ ^YAl + ^ZMn. As Mn²⁺ content increases, progressive disorder takes place. This disorder is quantitatively lower than that of the ^ZMg in dravite, due to the low structural tolerance of the small Z cavity in the incorporation of larger cations by the ^ZR²⁺ → ^ZAl substitution. Relationships of direct proportionality between lattice parameters and both <Y-O> and <Z-O> are observed. The expansion of both octahedra, as well as of lattice parameters, increases linearly as a function of ^YMn²⁺ and ^ZMn²⁺. The latter has greater weight in dictating unit-cell variations, due to the degree of size mismatch between ^ZMn²⁺ → ^ZAl and ^YMn²⁺ → ^YLi substitutions, and the way in which the Z octahedra are articulated in the structure.