BepiColomboプロジェクトチーム

梶谷 伊織

カジタニ イヲリ  (Iori Kajitani)

基本情報

所属
国立研究開発法人宇宙航空研究開発機構 宇宙科学研究所月惑星探査データ解析グループ(JLPEDA) 研究開発員

J-GLOBAL ID
202401014800630610
researchmap会員ID
R000064388

論文

 4
  • Iori Kajitani, Mizuho Koike, Ryoichi Nakada, Gaku Tanabe, Tomohiro Usui, Fumihiro Matsu'ura, Keisuke Fukushi, Tetsuya Yokoyama
    Earth and Planetary Science Letters 620 118345-118345 2023年10月  査読有り筆頭著者
  • Fumihiro Matsu'ura, Ryoichi Nakada, Tomohiro Usui, Yusuke Sawaki, Yuichiro Ueno, Iori Kajitani, Masafumi Saitoh
    GEOCHIMICA ET COSMOCHIMICA ACTA 306 20-43 2021年8月  
    The Ediacaran period was characterized by numerous events, including the emergence of large multi-cellular metazoans and surface environmental perturbations. This period was also characterized by an increase in atmospheric oxygen concentrations that was critical for the evolution of life. Oceanic sulfate concentrations varied in association with atmospheric oxygen concentrations, which have been constrained by sulfur isotopic compositions of sedimentary sulfates and pyrite, and sulfur concentrations of pyrite and carbonate associated sulfate (CAS). However, other parameters such as sedimentation rate or iron availability have a strong impact on the abundance and isotopic composition of pyrite. In addition, recent studies have demonstrated that some Phanerozoic limestones include a mix of various carbonate minerals, the compositions and diagenetic histories of which differ at the mu m scale. Thus, the mu m scale description of sulfur species is necessary to accurately extract information preserved in carbonate rocks. In this study, we investigated the speciation and concentrations of sulfur in the matrix of the Ediacaran Doushantuo and Dengying limestones exposed in South China using mu-X-ray fluorescence (XRF) mapping and S K-edge X-ray absorption near edge structure (XANES) analyses. In addition to pyrite, the XANES spectra of the Doushantuo limestone indicate that sulfur occurs as CAS, while the Dengying limestone contains CAS and abundant organic sulfur. Pyrite oxidation and re-mineralization of organic sulfur had little influence on CAS content in the samples, whereas sparitization produced decreases in CAS and organic sulfur concentrations. The CAS content of the Dengying sparite was lower than that of the Dengying micrite, indicating that the CAS content decreased even during marine diagenesis. Thus, the micrite is more appropriate for extracting paleo-oceanic information. On the other hand, variations in the CAS concentrations of the limestone matrix in the Dengying Formation were larger than those in the Doushantuo Formation, regardless of grain size. The large variations in the Dengying limestone resulted from local alkalinity fluctuations caused by temporal changes in microbial activity within microbial mats. Existence of abundant organic sulfur in the Dengying limestones has another implication to ancient sedimentary environment. The low pyrite content of the Dengying limestone is likely due to a deficient supply of reactive iron to the sediment-water interface, because the supply of organic matter was likely sufficient. (C) 2021 Elsevier Ltd. All rights reserved.
  • Ryoichi Nakada, Gaku Tanabe, Iori Kajitani, Tomohiro Usui, Masashi Shidare, Tetsuya Yokoyama
    Minerals 11(2) 176-176 2021年2月8日  
  • Mizuho Koike, Ryoichi Nakada, Iori Kajitani, Tomohiro Usui, Yusuke Tamenori, Haruna Sugahara, Atsuko Kobayashi
    Nature Communications 11(1) 2020年4月24日  査読有り
    Abstract Understanding the origin of organic material on Mars is a major issue in modern planetary science. Recent robotic exploration of Martian sedimentary rocks and laboratory analyses of Martian meteorites have both reported plausible indigenous organic components. However, little is known about their origin, evolution, and preservation. Here we report that 4-billion-year-old (Ga) carbonates in Martian meteorite, Allan Hills 84001, preserve indigenous nitrogen(N)-bearing organics by developing a new technique for high-spatial resolution in situ N-chemical speciation. The organic materials were synthesized locally and/or delivered meteoritically on Mars during Noachian age. The carbonates, alteration minerals from the Martian near-surface aqueous fluid, trapped and kept the organic materials intact over long geological times. This presence of N-bearing compounds requires abiotic or possibly biotic N-fixation and ammonia storage, suggesting that early Mars had a less oxidizing environment than today.