期刊
GEOCHEMICAL PERSPECTIVES LETTERS
卷 8, 期 -, 页码 31-35出版社
EUROPEAN ASSOC GEOCHEMISTRY
DOI: 10.7185/geochemlet.1826
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资金
- Department of Energy Computational Science Graduate Fellowship Program of the Office of Science and National Nuclear Security Administration [DE- FG02-97ER25308]
- U.S. Department of Energy, National Nuclear Security Administration [DE-AC52-07NA27344]
The accessory mineral zircon is widely used to constrain the timing of igneous processes such as magma crystallisation or eruption. However, zircon U-Pb ages record zircon crystallisation, which is not an instantaneous process. Zircon saturation calculations link zircon crystallisation, temperature, and melt fraction, allowing for the estimation of zircon crystallisation distributions as a function of time or temperature. Such distributions provide valuable prior information, enabling Bayesian estimates of magma eruption time and allowing for comparison of the relative accuracy of common weighted-mean and youngest-zircon age interpretations with synthetic datasets. We find that both traditional interpretations carry a risk of underestimating the uncertainty in eruption age; a low mean square of weighted deviates (MSWD) does not guarantee the accuracy of weighted-mean interpretations. In the absence of independent confirmation that crystallisation timescale is short relative to analytical uncertainties, a Bayesian approach frequently provides the most accurate results and is least likely to underestimate uncertainty. Since U-Pb zircon studies now routinely resolve geological age dispersion due to increasing analytical precision, such considerations are increasingly critical to future progress in resolving rates and dates of Earth processes.
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