Journal
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume 112, Issue 17, Pages 5331-5336Publisher
NATL ACAD SCIENCES
DOI: 10.1073/pnas.1501658112
Keywords
hafnium isotopes; chondritic uniform reservoir; bulk silicate Earth; early Earth differentiation; meteorite zircon
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Funding
- Australian Research Council
- Japan Society for the Promotion of Science
- Grants-in-Aid for Scientific Research [15H02149, 25707042] Funding Source: KAKEN
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Knowledge of planetary differentiation is crucial for understanding the chemical and thermal evolution of terrestrial planets. The Lu-176-Hf-176 radioactive decay system has been widely used to constrain the timescales and mechanisms of silicate differentiation on Earth, but the data interpretation requires accurate estimation of Hf isotope evolution of the bulk Earth. Because both Lu and Hf are refractory lithophile elements, the isotope evolution can be potentially extrapolated from the present-day Hf-176/Hf-177 and Lu-176/Hf-177 in undifferentiated chondrite meteorites. However, these ratios in chondrites are highly variable due to the metamorphic redistribution of Lu and Hf, making it difficult to ascertain the correct reference values for the bulk Earth. In addition, it has been proposed that chondrites contain excess Hf-176 due to the accelerated decay of Lu-176 resulting from photoexcitation to a short-lived isomer. If so, the paradigm of a chondritic Earth would be invalid for the Lu-Hf system. Herein we report the first, to our knowledge, high-precision Lu-Hf isotope analysis of meteorite crystalline zircon, a mineral that is resistant to metamorphism and has low Lu/Hf. We use the meteorite zircon data to define the Solar System initial Hf-176/Hf-177 (0.279781 +/- 0.000018) and further to identify pristine chondrites that contain no excess Hf-176 and accurately represent the Lu-Hf system of the bulk Earth (Hf-176/Hf-177 = 0.282793 +/- 0.000011; Lu-176/Hf-177 = 0.0338 +/- 0.0001). Our results provide firm evidence that the most primitive Hf in terrestrial zircon reflects the development of a chemically enriched silicate reservoir on Earth as far back as 4.5 billion years ago.
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