Litcius/Paper detail

Nanophase Iron Particles Derived From Fayalitic Olivine Decomposition in Chang'E‐5 Lunar Soil: Implications for Thermal Effects During Impacts

Zhuang Guo, Chen Li, Yang Li, Yuanyun Wen, Kairui Tai, Xiongyao Li, Jianzhong Liu, Ziyuan Ouyang

2022Geophysical Research Letters73 citationsDOIOpen Access PDF

Abstract

Abstract Surface‐correlated nanophase iron particles (npFe 0 ) alter the reflectance spectrum characteristics of airless bodies, thus making it an essential aspect of studying space weathering. Vapor deposition has been the only strongly proven npFe 0 formation mechanism owing to the long exposure time of Apollo samples, whereas other formation mechanisms remain questioned. Newly returned younger Chang'E‐5 samples provide an opportunity to study the incipient formation mechanism of npFe 0 . Here, we combined transmission electron microscopy and electron energy loss spectroscopy to characterize the microscopic features of Chang'E‐5 olivine rims. The uppermost layer of these grains exhibits the simultaneous coexistence of npFe 0 with Si‐rich material overlying an Mg‐rich layer, as well as numerous irregular vesicles containing oxygen‐rich (SiO and O 2 ) components embedded in the npFe 0 . These microscopic features collectively suggest subsolidus olivine decomposition during (micro)impact‐induced fragmentation or local heating processes, which may be the essential agent to alter the reflectance spectrum of airless bodies.

Topics & Concepts

OlivineSpace weatheringMineralogyTransmission electron microscopyMeteoriteAstrobiologyMaterials scienceDecompositionElectron energy loss spectroscopyWeatheringChemical physicsChemical engineeringGeologyChemistryNanotechnologyGeochemistryAsteroidEngineeringPhysicsOrganic chemistryPlanetary Science and ExplorationAstro and Planetary ScienceGeomagnetism and Paleomagnetism Studies