日本地球惑星科学連合2019年大会

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[J] 口頭発表

セッション記号 M (領域外・複数領域) » M-GI 地球科学一般・情報地球科学

[M-GI34] 海底マンガン鉱床の環境,開発,地球史

2019年5月28日(火) 15:30 〜 17:00 A09 (東京ベイ幕張ホール)

コンビーナ:臼井 朗(高知大学海洋コア総合研究センター)、高橋 嘉夫(東京大学大学院理学系研究科地球惑星科学専攻)、鈴木 勝彦(国立研究開発法人海洋研究開発機構・海底資源研究開発センター)、伊藤 孝(茨城大学教育学部)、座長:伊藤 孝(茨城大学)、高橋 嘉夫(東京大学)、鈴木 勝彦(JAMSTEC)

16:00 〜 16:15

[MGI34-03] 深海底化学堆積物・鉄マンガンクラストにおけるZr, Hfの分別挙動

*坂口 綾1稲垣 純平1井上 美南2臼井 朗3羽場 宏光4金子 政志5山﨑 信哉1末木 啓介1高橋 嘉夫6 (1.筑波大学数理物質系、2.広島大学大学院理学研究科、3.高知大学海洋コア総合研究センター、4.理化学研究所仁科加速器科学研究センター、5.日本原子力研究開発機構原子力基礎工学研究センター、6.東京大学大学院理学系研究科)

キーワード:鉄マンガンクラスト、ジルコニウム、ハフニウム

Ferromanganese crusts (FMCs) are abyssal benthic chemical sediments that consist mainly of Fe and Mn oxide and hydroxide minerals, enriched with trace and precious metals. Due to their similar physicochemical properties, the elements zirconium (Zr) and hafnium (Hf), which are concentrated in FMCs, have a theoretically uniform ratio (Zr/Hf), which ratio is found in numerous systems. However, recent advances in analytical techniques have allowed observation of significant differences in the fractionation of these elements between seawater (Zr/Hf~45-350; Firdaus et al. 2011) and FMCs (Zr/Hf~57-88; Schmidt et al., 2014). In this study, we conducted adsorption experiments and XAFS analyses to clarify the concentrations and fractionation mechanisms of Zr-Hf in FMCs using synthesized minerals (Ferrihydrite and δ-MnO2), radio-Zr and Hf tracers, and natural samples.

Six FMCs were collected from the Takuyo-Daigo and Ryusei seamounts, at water depths of from 950 m to 3000 m, using a ROV equipped with a live video camera and manipulators. The near surface layers (less than 1 mm) of all the FMCs were analyzed with XAFS and ICP-MS for Zr, Hf and other elements, and with XRD for mineral composition. Radiotracers were produced using the RIKEN AVF cyclotron for adsorption and co-precipitation experiments. Appropriate amounts of these tracers were added to 0.7 M NaCl solutions containing desferrioxamine B (DFOB) to obtain some Zr and Hf concentrations of solutions. The speciations of these elements in said solutions were confirmed by ESI-TOF-MS. Synthesized Ferrihydrite or δ-MnO2 was added to the solutions and stirred for three hours at a pH of 8. In addition, Ferrihydrite or δ-MnO2 was synthesized in said solutions. The activities of radio tracers in the filtered solutions were measured using a Ge detector. The adsorption/co-precipitation amounts to the solid phase were calculated using the differences in the radioactivity of the solution before and after filtration.

The major mineral composition of Fe and Mn in the FMCs did not vary significantly with the water depth of these seamounts. The concentrations of Zr and Hf increased with depth, and their ratios were totally fractionated from those of the seawater (Firdaus et al., 2011). Hf was more enriched in all FMCs than was Zr. The observed Zr chemical states in the FMCs were mainly coprecipitation with Ferrihydrite and coprecipitation with d-MnO2. In our adsorption experiments, the largest adsorption rate was observed in Hf to δ-MnO2, followed in order by Zr to δ-MnO2, Hf to Ferrihydrite and Zr to Ferrihydrite. The partition coefficients (KD values) were calculated using the concentration ranges of Zr and Hf in seawater, where it was clear that Hf adsorbed more on both. Even though complexation rates estimated by RI-TLC were considered, there was no change in the adsorption behaviors in these experiments. For these samples, we found that the bond lengths between Zr-O and Hf-O in the first shells were shortened when they were incorporated into the oxides, with Hf-O becoming more shortened compared to Zr-O. The DFT calculations showed that Zr and Hf adsorbs on Fe and Mn oxides as bidentate-mono nuclear and bidentate-binuclear structures. The calculation results for the binding energies and bond orders of Zr and Hf to minerals gave a reasonable explanation of the fractionation mechanism for Zr-Hf pairs in FMCs.