Affiliation:
1. Department of Earth Sciences University of Adelaide 5005 South Australia Australia
2. Current address: Institute for Geology University of Bern Baltzerstrasse 1 + 3 Bern 3012 Switzerland
3. Adelaide Microscopy University of Adelaide 5005 South Australia Australia
4. Mineral Exploration Cooperative Research Centre University of Adelaide 5005 Australia
5. John de Laeter Centre Curtin University Bentley 6845 Western Australia Australia
Abstract
Re‐Os isotope‐dilution geochronology has been widely used to date the timing of molybdenite, pyrite and chalcopyrite formation across a variety of geological settings. However, in situ methods have been impeded by the isobaric interference of 187Re on 187Os. In situ Re‐Os geochronology using LA‐ICP‐MS/MS has been shown to be a useful technique to chemically separate Os from Re, as Os reacts with CH4 to create higher‐mass reaction products, which can then be measured with minimised interference of 187Re. However, application of the method requires matrix‐matched primary reference materials, e.g., age‐homogenous molybdenite amenable to laser ablation. Here, we characterise and present two new molybdenite mineral reference materials for in situ Re‐Os geochronology by LA‐ICP‐MS/MS, verified by ID‐TIMS Re‐Os measurements. We also present case studies from molybdenite samples with varying Re mass fractions and Re‐Os age mapping. The method provides accurate and precise age data, with excellent precision for high Re samples. The benefits of the LA‐ICP‐MS/MS approach include: (1) simple sample preparation, (2) rapid data acquisition, (3) targeting of specific textural domains including growth zones and (4) the ability to simultaneously collect trace elements used to link the timing and conditions of ore‐formation.
Funder
Australian Research Council