化学科

Takeshi Ohno

  (大野 剛)

Profile Information

Affiliation
Assistant Professor, Faculty of ScienceDepartment of Chemistry, Gakushuin University
Degree
博士(理学)(Mar, 2006, 東京工業大学)

J-GLOBAL ID
200901073704385612
researchmap Member ID
5000085744

Research Interests

 2

Papers

 47
  • Takashi Yuguchi, Kyoka Endo, Satoshi Suzuki, Yasuhiro Ogita, Shuhei Sakata, Tatsunori Yokoyama, Takumi Imura, Takeshi Ohno, Eiji Sasao
    Lithos, 494-495 107909-107909, Feb, 2025  
  • Yusuke Sawaki, Hisashi Asanuma, Shuhei Sakata, Mariko Abe, Hisahiro Ueda, Wataru Fujisaki, Takeshi Ohno
    Island Arc, 33(1), Nov, 2024  Peer-reviewed
    ABSTRACT Owing to high resistance to alteration, detrital zircons retain information about their formation ages and parental magmas for a long period of time. Many geochemical researchers have proposed various indicators for zircon to constrain tectonic settings and to identify source rock. Because most detrital zircons analyzed by geochronologic studies are derived primarily from granitoids, we focus on the classification of zircon within granitoids. In the style of alphabetical classification scheme (Igneous, I; Sedimentary, S; and Alkaline, A types), some discrimination diagrams have been proposed. To improve the database and enhance discriminating studies, we examined trace‐element compositions of zircons extracted from some Cenozoic granitoids exposed in the Japan Islands. The zircons showed systematic differences in Nb, Ta, Ce, and P contents. Zircons in Oceanic Arc I‐type granite are poor in Nb and Ta, and these signatures clearly reflect those elements in their parental bodies. Despite their low abundance at the whole‐rock level, zircons in Oceanic Arc I‐type granite are characterized by high Ce content. This is attributable to the relatively oxidizing conditions of Oceanic Arc I‐type magma. Zircons in S‐type granite are characterized by high P and low Ce contents. The former can be explained by high apatite solubility in Al‐rich magma, whereas the reducing environment of S‐type magma is accountable for the latter. The zircon crystallized at the later stage during S‐type granite solidification is slightly depleted in Nb and Ta. This is attributable to the depletion of these elements in the magma by Ti‐bearing minerals such as ilmenite prior to zircon crystallization. In analogy with whole‐rock composition, zircons in transitional I‐A‐type granite have intermediate composition between I‐type and A‐type zircons. On the basis of the updated database, we demonstrated that the Nb/P–Ce/P or Ta/P–Ce/P crossplots are the most useful for discriminating zircons in Oceanic Arc I‐type, I‐type, S‐type, and A‐type granites.
  • Kota Yamamoto, Takeshi Ohno, Gou Kitamura, Hiroaki Takahashi, Takafumi Hirata
    Environmental Technology & Innovation, 103761-103761, Jul, 2024  Peer-reviewed
  • Yusuke Fukami, Ryoko Ariizumi, Yuta Ijichi, Takeshi Ohno, Teruhiko Kashiwabara, Takazo Shibuya, Katsuhiko Suzuki, Takafumi Hirata
    Proceedings of the National Academy of Sciences of the United States of America, 121(17) e2321616121, Apr 23, 2024  Peer-reviewed
    Experimental results are presented showing the variation in the relationship between odd isotopes of tin (Sn) in mass-independent fractionation caused by the magnetic isotope effect (MIE), which has previously only been observed for mercury. These results are consistent with the trend predicted from the difference between the magnitudes of nuclear magnetic moments of odd isotopes with a nuclear spin. However, the correlation between odd isotopes in fractionation induced by the MIE for the reaction system used in this study (solvent extraction using a crown ether) was different from that reported for the photochemical reaction of methyltin. This difference between the two reaction systems is consistent with a theoretical prediction that the correlation between odd isotopes in fractionation induced by the MIE is controlled by the relationship between the spin conversion time and radical lifetime. The characteristic changes in the correlation between odd isotopes in fractionation induced by the MIE observed for Sn in this study provide a guideline for quantitatively determining fractionation patterns caused by the MIE for elements that have multiple isotopes with a nuclear spin. These results improve our understanding of the potential impact of the MIE on mass-independent fractionation observed in natural samples, such as meteorites, and analytical artifacts of high-precision isotope analysis for heavy elements.
  • Takashi Yuguchi, Takenori Kato, Yasuhiro Ogita, Minori Watanabe, Hayoto Yamazaki, Asuka Kato, Daichi Itoh, Tatsunori Yokoyama, Shuhei Sakata, Takeshi Ohno
    Journal of Asian Earth Sciences, 265 106091-106091, Apr, 2024  Peer-reviewed

Misc.

 12

Books and Other Publications

 1

Presentations

 121

Research Projects

 12