日本地球惑星科学連合2015年大会

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セッション記号 S (固体地球科学) » S-GC 固体地球化学

[S-GC51] 希ガス同位体地球惑星科学の最前線

2015年5月24日(日) 16:15 〜 18:00 A04 (アパホテル&リゾート 東京ベイ幕張)

コンビーナ:*兵藤 博信(岡山理科大学自然科学研究所)、角野 浩史(東京大学大学院理学系研究科附属地殻化学実験施設)、田上 高広(京都大学大学院理学研究科)、座長:兵藤 博信(岡山理科大学自然科学研究所)、角野 浩史(東京大学大学院理学系研究科附属地殻化学実験施設)

17:30 〜 17:45

[SGC51-09] イトカワ試料の形態的特徴と希ガス同位体組成との関係

*野口 高明1岡崎 隆司1光成 拓也2飛松 優1上椙 真之3矢田 達3唐牛 譲3日高 洋4木村 眞2 (1.九州大学、2.茨城大学、3.宇宙航空研究開発機構、4.広島大学)

Introduction: Fine-grained particles of the asteroid Itokawa preserve the effects related to the processes on and near the surface of an asteroid. Various types of surface modification were found on the very surface (<100 nm) [1-6]. The modification textures suggest that irradiation by solar wind (SW) plays an important role for their formation. Number density of solar flare tracks in them ranges from a few × 109 to a few × 1010 tracks/cm2 [2, 5], which are considerably lower than expected. These data suggest the mechanisms and periods of the surface modification of Itokawa grains are still unresolved. In addition to the SW irradiation, there seems to have been another mechanism that modified the morphology and surface features of the grains. Matsumoto et al. [3] found some Itokawa grains were aggregates composed of subgrains with stepped surfaces, which suggests evaporation and/or condensation. Noble gas mass spectrometry is another tool to infer the individual history of each Itokawa grain. Nagao et al. [7] argued that a grain experienced multiple processes: exposure to SW, burial in the regolith layer, and removal of its external surface. We intend to investigate the relationships among morphology, surface modifications, and noble gas isotopic signatures to discuss the history of each Itokawa particle from various perspectives.
Samples and methods:. We fixed four Itokawa particles on tantalum plates by acetone-soluble glue. We observed the surface of the particles and prepared thin foils by FIB-SEM at Ibaraki University. After preparation of FIB foils, all the Ta plates with samples rinsed by acetone in a N2 filled glove box. They were transferred to Kyushu University and noble gas mass spectrometry was performed for all the noble gas elements using a modified VG-5400. Noble gas extraction from each sample was conducted stepwise at 50, 100, 200, 300, 600 and 1400 ℃.
Results and discussion:. SEM observation of the four Itokawa grains investigated shows various morphology and surface features. Edges observed on the surfaces of three grains vary from sharp to dull. Additionally, one grain is composed of two subgrains with stepped surfaces. Morphology and surface features are related to the He release patterns. The three particles have similar 4He release patterns; they release most 4He below 200 ℃ fractions and a small amount of 4He above 600 ℃. Although the gas-release profiles are similar to each other, there is a difference in the bulk concentrations of 4He; one of the three grain having dull edges contain more abundant 4He than the others having sharp edges. Because bulk 3He/4He ratios in the three grains are 2.5 to 6.5 ×10-4, which is comparable with that in the solar wind of 4.57 ×10-4 [8], it is likely that the implanted He in the grains increased as the surfaces were degraded by solar wind sputtering. On the other hand, the grain composed of subgrains with stepped surfaces shows a different 4He release pattern; 4He was released only below 200 ℃. This fact suggests that deeply implanted He, which is probably related to He released above 600 ℃, was completely reset by severe heating. The steps on the surfaces of this grain may have been formed by evaporation and/or evaporation and subsequent recondensation by a heating event, which released He from the interior of the grain. These results strongly suggest that micrometer-size surface features are related to the amounts and the release patterns of the implanted He.
References: [1] Noguchi et al. (2011) Science 333, 1121-1125. [2] Noguchi et al. (2014) Meteorit. Planet. Sci. 49, 188-214. [3] Matsumoto et al. (2013) 44th Lunar Planet. Sci. Conf. abstr. #1441. [4] Thompson et al. (2014) Earth Planet. Space 66, 89-99. [5] Keller and Berger (2014) Earth Planet. Space 66, 71-78. [6] Noguchi et al. (2014) Earth Planet. Space 66, 124-134. [7] Nagao et al. (2011) Science 333, 1128-1131. [8] Heber et al. (2009) Geochim. Cosmochim. Acta 73, 7414-7432.