Transfer of rare earth elements (REE) from manganese oxides to phosphates during early diagenesis in pelagic sediments inferred from REE patterns, X-ray absorption spectroscopy, and chemical leaching method

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doi: 10.2343/geochemj.2.0393
Author(s): Takahashi, Yoshio; Hayasaka, Yasutaka; Morita, Koichi; Kashiwabara, Teruhiko; Nakada, Ryoichi; Marcus, Matthew A.; Kato, Kenji; Tanaka, Kazuya; Shimizu, Hiroshi
Author Affiliation(s): Primary:
University of Tokyo, Department of Earth and Planetary Science, Tokyo, Japan
Hiroshima University, Japan
Lawrence Berkeley National Laboratory, United States
Shizuoka University, Japan
Volume Title: Front edge of submarine mineral resources research in Japan
Volume Author(s): Suzuki, Katsuhiko, prefacer; Ishibashi, Jun-ichiro; Kato, Yasuhiro; Nozaki, Tatsuo
Source: Front edge of submarine mineral resources research in Japan, prefaced by Katsuhiko Suzuki, Jun-ichiro Ishibashi, Yasuhiro Kato and Tatsuo Nozaki. Geochemical Journal, 49(6), p.653-674. Publisher: Geochemical Society of Japan, Nagoya, Japan. ISSN: 0016-7002 CODEN: GEJOBE
Note: In English. 71 refs.; illus., incl. 5 tables
Summary: The migration of REEs in pelagic siliceous sediments were studied, especially (i) accumulation of REEs at sea floor to Mn4+ oxides, (ii) release of REEs from Mn4+ oxides accompanied with the reductive dissolution of Mn4+ oxides during early diagenesis, and (iii) incorporation and fixation of REEs released from Mn4+ oxides to phosphates such as apatite below 0.6 meters below sea floor (mbsf). These processes have been indicated by various geochemical findings: (a) chemical compositions of bulk sediment and pore water, (b) REE patterns of bulk sediment, (c) oxidation states of Ce, Mn, and Fe and host phase of Y by XANES, and (d) chemistry of specific phases such as Mn4+ oxides and apatite by means of chemical leaching, LA-ICP-MS, and XANES. The roles of Mn4+ oxides and apatite as host phases of REEs at sea floor and below 0.6 mbsf, respectively, were discussed using the chemical leaching data. Reductive dissolution of Mn4+ oxides and reduction of Ce3+ to Ce4+ with depth were revealed by direct determination of oxidation states of Mn and Ce by XANES. The transfer of REEs released by the reductive dissolution of Mn4+ oxides is strongly suggested by the presence of positive Ce anomalies in apatite at 0.80 mbsf (LA-ICP-MS) and at 1.80 mbsf (chemical leaching), which must be inherited from Mn4+ oxides which can accumulate Ce by oxidizing Ce3+ to Ce4+. This observation shows that apatite fixes the REEs with positive Ce anomaly once dissolved from Mn4+ oxides during early diagenesis. Consequently, we found that total REEs in the two phases (Mn4+ oxides and apatite) are preserved even after diagenetic alteration, because apatite fixes the most of the REEs released from Mn4+ oxides. The results indicate two geochemical implications: (i) REE abundances in apatite in sediment, which has attracted great interests in terms of REE resources, depend on the amount of REEs fixed in Mn (and Fe) oxides initially formed at the sediment surface, and then apatite finally fixes the REEs during early diagenesis; (ii) the reliability of apatite as a proxy of seawater chemistry is affected seriously by the overprint of REE signature by the diagenetic effect. However, if the contribution of REEs in Mn (and Fe) oxide is small, then the REE pattern of apatite can preserve information of the REE pattern of seawater, including the degree of Ce anomaly.
Year of Publication: 2015
Research Program: ODP Ocean Drilling Program
Key Words: 02 Geochemistry; 27 Economic Geology, Metals; Apatite; Cerium; Chemical composition; Diagenesis; Early diagenesis; Experimental studies; Geochemical anomalies; ICP mass spectra; Leaching; Leg 191; Manganese oxides; Marine sediments; Mass spectra; Metal ores; Metals; Migration of elements; Mineral resources; North Pacific; Northwest Pacific; ODP Site 1179; Ocean Drilling Program; Ocean floors; Oxides; Pacific Ocean; Pelagic environment; Phosphates; Rare earths; Sea water; Sediments; Spectra; West Pacific; X-ray spectra; XANES spectra
Coordinates: N410400 N410500 E1595800 E1595700
Record ID: 2017042807
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