کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
6427927 | 1634726 | 2015 | 7 صفحه PDF | دانلود رایگان |
- We report Fe isotope compositions of lunar meteorites and Apollo samples.
- Lunar dunite 72â415 is enriched in light Fe isotopes, unlike any other lunar samples.
- The heavy Fe isotope in the shallow Moon can be balanced with light Fe in the deep.
- The Lunar Magma Ocean differentiation has fractionated the Fe isotopes of the Moon.
- The Fe isotope composition of the Moon is most likely identical to that of the Earth.
Recent high-precision isotopic measurements show that the isotopic similarity of Earth and Moon is unique among all known planetary bodies in our Solar System. These observations provide fundamental constraints on the origin of Earth-Moon system, likely a catastrophic Giant Impact event. However, in contrast to the isotopic composition of many elements (e.g., O, Mg, Si, K, Ti, Cr, and W), the Fe isotopic compositions of all lunar samples are significantly different from those of the bulk silicate Earth. Such a global Fe isotopic difference between the Moon and Earth provides an important constraint on the lunar formation - such as the amount of Fe evaporation as a result of a Giant Impact origin of the Moon. Here, we show through high-precision Fe isotopic measurements of one of the oldest lunar rocks (4.51±0.10Gyr dunite 72â415), compared with Fe isotope results of other lunar samples from the Apollo program, and lunar meteorites, that the lunar dunite is enriched in light Fe isotopes, complementing the heavy Fe isotope enrichment in other lunar samples. Thus, the earliest olivine accumulation in the Lunar Magma Ocean may have been enriched in light Fe isotopes. This new observation allows the Fe isotopic composition of the bulk silicate Moon to be identical to that of the bulk silicate Earth, by balancing light Fe in the deep Moon with heavy Fe in the shallow Moon rather than the Moon having a heavier Fe isotope composition than Earth as a result of Giant Impact vaporization.
Journal: Earth and Planetary Science Letters - Volume 430, 15 November 2015, Pages 202-208