Fe, Zn, and Mg stable isotope systematics of acapulcoite lodranite clan meteorites

IF 2.2 4区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
Stepan M. Chernonozhkin, Lidia Pittarello, Genevieve Hublet, Philippe Claeys, Vinciane Debaille, Frank Vanhaecke, Steven Goderis
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引用次数: 0

Abstract

The processes of planetary accretion and differentiation, whereby an unsorted mass of primitive solar system material evolves into a body composed of a silicate mantle and metallic core, remain poorly understood. Mass-dependent variations of the isotope ratios of non-traditional stable isotope systems in meteorites are known to record events in the nebula and planetary evolution processes. Partial melting and melt separation, evaporation and condensation, diffusion, and thermal equilibration between minerals at the parent body (PB) scale can be recorded in the isotopic signatures of meteorites. In this context, the acapulcoite–lodranite meteorite clan (ALC), which represents the products of thermal metamorphism and low-degree partial melting of a primitive asteroid, is an attractive target to study the processes of early planetary differentiation. Here, we present a comprehensive data set of mass-dependent Fe, Zn, and Mg isotope ratio variations in bulk ALC species, their separated silicate and metal phases, and in handpicked mineral fractions. These non-traditional stable isotope ratios are governed by mass-dependent isotope fractionation and provide a state-of-the-art perspective on the evolution of the ALC PB, which is complementary to interpretations based on the petrology, trace element composition, and isotope geochemistry of the ALC. None of the isotopic signatures of ALC species show convincing co-variation with the oxygen isotope ratios, which are considered to record nebular processes occurring prior to the PB formation. Iron isotopic compositions of ALC metal and silicate phases broadly fall on the isotherms within the temperature ranges predicted by pyroxene thermometry. The isotope ratios of Mg in ALC meteorites and their silicate minerals are within the range of chondritic meteorites, with only accessory spinel group minerals having significantly different compositions. Overall, the Mg and Fe isotopic signatures of the ALC species analyzed are in line with their formation as products of high-degree thermal metamorphism and low-degree partial melting of primitive precursors. The δ66/64Zn values of the ALC meteorites demonstrate a range of ~3.5‰ and the Zn is overall isotopically heavier than in chondrites. The superchondritic Zn isotopic signatures have possibly resulted from evaporative Zn losses, as observed for other meteorite parent bodies. This is unlikely to be the result of PB differentiation processes, as the Zn isotope ratio data show no covariation with the proxies of partial melting, such as the mass fractions of the platinum group and rare earth elements.

Abstract Image

阿卡普尔科岩珞珈山族陨石的铁、锌和镁稳定同位素系统学
行星的吸积和分化过程,即一团未经分拣的原始太阳系物质演变成一个由硅酸盐地幔和金属内核组成的天体的过程,仍然鲜为人知。众所周知,陨石中非传统稳定同位素系统的同位素比率随质量的变化记录了星云和行星演化过程中的事件。在母体(PB)尺度上,部分熔化和熔体分离、蒸发和冷凝、扩散以及矿物之间的热平衡都可以记录在陨石的同位素特征中。在这种情况下,代表原始小行星热变质和低度部分熔化产物的阿卡普尔科岩-洛德兰特陨石群(ALC)是研究早期行星分化过程的一个有吸引力的目标。在这里,我们展示了一个综合数据集,其中包括大块ALC物种、其分离的硅酸盐和金属相以及精选矿物碎片中与质量相关的铁、锌和镁同位素比值变化。这些非传统的稳定同位素比值受质量依赖性同位素分馏的影响,为研究 ALC PB 的演化提供了最新视角,与基于 ALC 岩石学、微量元素组成和同位素地球化学的解释相辅相成。ALC 物种的同位素特征均未显示出令人信服的与氧同位素比值的共变,而氧同位素比值被认为记录了 PB 形成之前发生的星云过程。ALC 金属和硅酸盐相的铁同位素组成大致落在辉石温度测定法预测的温度范围内的等温线上。ALC 陨石及其硅酸盐矿物中镁的同位素比值在软玉陨石的范围内,只有附属尖晶石类矿物的成分有显著差异。总体而言,所分析的 ALC 物种的镁和铁同位素特征符合它们作为原始前体的高度热变质和低度部分熔化产物的形成过程。ALC陨石的δ66/64Zn值范围约为3.5‰,Zn的同位素含量总体上重于软玉。正如在其他陨石母体中观察到的那样,超软玉锌同位素特征可能是由于蒸发锌损失造成的。这不太可能是 PB 分化过程的结果,因为锌同位素比值数据与部分熔化的代用指标(如铂族元素和稀土元素的质量分数)没有共变关系。
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来源期刊
Meteoritics & Planetary Science
Meteoritics & Planetary Science 地学天文-地球化学与地球物理
CiteScore
3.90
自引率
31.80%
发文量
121
审稿时长
3 months
期刊介绍: First issued in 1953, the journal publishes research articles describing the latest results of new studies, invited reviews of major topics in planetary science, editorials on issues of current interest in the field, and book reviews. The publications are original, not considered for publication elsewhere, and undergo peer-review. The topics include the origin and history of the solar system, planets and natural satellites, interplanetary dust and interstellar medium, lunar samples, meteors, and meteorites, asteroids, comets, craters, and tektites. Our authors and editors are professional scientists representing numerous disciplines, including astronomy, astrophysics, physics, geophysics, chemistry, isotope geochemistry, mineralogy, earth science, geology, and biology. MAPS has subscribers in over 40 countries. Fifty percent of MAPS'' readers are based outside the USA. The journal is available in hard copy and online.
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