Argon behaviour in an inverted Barrovian sequence, Sikkim Himalaya: The consequences of temperature and timescale on 40Ar/39Ar mica geochronology

Catherine M. Mottram*, Clare J. Warren, Alison M. Halton, Simon P. Kelley, Nigel B.W. Harris

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

40Ar/39Ar dating of metamorphic rocks sometimes yields complicated datasets which are difficult to interpret in terms of timescales of the metamorphic cycle. Single-grain fusion and step-heating data were obtained for rocks sampled through a major thrust-sense shear zone (the Main Central Thrust) and the associated inverted metamorphic zone in the Sikkim region of the eastern Himalaya. This transect provides a natural laboratory to explore factors influencing apparent 40Ar/39Ar ages in similar lithologies at a variety of metamorphic pressure and temperature (P-T) conditions. The 40Ar/39Ar dataset records progressively younger apparent age populations and a decrease in within-sample dispersion with increasing temperature through the sequence. The white mica populations span ~2-9Ma within each sample in the structurally lower levels (garnet grade) but only ~0-3Ma at structurally higher levels (kyanite-sillimanite grade). Mean white mica single-grain fusion population ages vary from 16.2±3.9Ma (2σ) to 13.2±1.3Ma (2σ) from lowest to highest levels. White mica step-heating data from the same samples yields plateau ages from 14.27±0.13Ma to 12.96±0.05Ma. Biotite yield older apparent age populations with mean single-grain fusion dates varying from 74.7±11.8Ma (2σ) at the lowest structural levels to 18.6±4.7Ma (2σ) at the highest structural levels; the step-heating plateaux are commonly disturbed. Temperatures >600°C at pressures of 0.4-0.8GPa sustained over >5Ma, appear to be required for white mica and biotite ages to be consistent with diffusive, open-system cooling. At lower temperatures, and/or over shorter metamorphic timescales, more 40Ar is retained than results from simple diffusion models suggest. Diffusion modelling of Ar in white mica from the highest structural levels suggests that the high-temperature rocks cooled at a rate of ~50-80°CMa-1, consistent with rapid thrusting, extrusion and exhumation along the Main Central Thrust during the mid-Miocene.

Original languageEnglish
Pages (from-to)37-51
Number of pages15
JournalLithos
Volume238
Early online date12 Sept 2015
DOIs
Publication statusPublished - 1 Dec 2015

Keywords / Materials (for Non-textual outputs)

  • Ar/Ar
  • Cooling
  • Ductile thrusting
  • Himalaya
  • Inverted metamorphism

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