Trace-element partitioning and boron isotope fractionation between white mica and tourmaline
Trace-element partitioning and boron isotope fractionation between white mica and tourmaline
The Canadian Mineralogist (February 2011) 49 (1): 165-176
- Australasia
- Australia
- B-11/B-10
- boron
- Broken Hill
- coexisting minerals
- ICP mass spectra
- ion probe data
- isotope fractionation
- isotopes
- laser ablation
- laser methods
- major elements
- mass spectra
- metamorphic rocks
- metasedimentary rocks
- mica group
- muscovite
- New South Wales Australia
- partitioning
- ring silicates
- sheet silicates
- silicates
- spectra
- stable isotopes
- tourmaline group
- trace elements
High-grade metamorphic tourmaline and white mica from the Broken Hill area, NSW, Australia, were analyzed with laser-ablation ICP-MS and ion-probe techniques to investigate the partitioning of trace elements and fractionation of boron isotopes between these two coexisting phases. The results indicate that most trace elements show partition coefficients close to one; only elements such as Zn, Sr, the light rare-earth elements La and Ce, and Th, partition preferentially into tourmaline, whereas Rb, Ba, W, Sn, and Nb and Ta are preferentially partitioned into coexisting mica. The ion-probe measurements demonstrate that boron isotopes are strongly fractionated between mica and tourmaline, with the white mica being some 10 per mil lower in delta (super 11) B than coexisting tourmaline, which is found to be in rather good agreement with previous measurements and predictions from theory.
