The +0.1‰ elevated 56Fe/54Fe ratio of terrestrial basalts relative to chondrites was proposed to be a fingerprint of core-mantle segregation. However, the extent of iron isotopic fractionation between molten metal and silicate under high pressure–temperature conditions is poorly known. Here we show that iron forms chemical bonds of similar strengths in basaltic glasses and iron-rich alloys, even at high pressure. From the measured mean force constants of iron bonds, we calculate an equilibrium iron isotope fractionation between silicate and iron under core formation conditions in Earth of ∼0–0.02‰, which is small relative to the +0.1‰ shift of terrestrial basalts. This result is unaffected by small amounts of nickel and candidate core-forming light elements, as the isotopic shifts associated with such alloying are small. This study suggests that the variability in iron isotopic composition in planetary objects cannot be due to core formation.
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机译:地面玄武岩相对于球粒陨石的+ 0.1‰升高的 56 Fe / 54 Fe比被认为是核幔分离的指纹。然而,在高温高压条件下,熔融金属和硅酸盐之间铁同位素分馏的程度知之甚少。在这里,我们证明即使在高压下,铁也会在玄武玻璃和富铁合金中形成具有相似强度的化学键。根据测得的铁键平均力常数,我们可以计算出在地球成核条件下,硅酸盐与铁之间的平衡铁同位素分馏约为0-0.02‰,这相对于地面玄武岩的+ 0.1‰位移而言很小。该结果不受少量镍和候选形成核的轻元素的影响,因为与这种合金化相关的同位素位移很小。这项研究表明,行星物体中铁同位素组成的变异性不能归因于岩心的形成。
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