熔融NaCl-CaCl2中福岛风化黑云母的电化学除Cs及晶体形成

Q3 Engineering

AIMS Electronics and Electrical Engineering Pub Date : 2019-03-03 DOI:10.3934/ELECTRENG.2019.2.102

M. Honda, T. Goto, Y. Sakanaka, T. Yaita, Shin'ichi Suzuki

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引用次数: 1

摘要

采用熔盐电化学(EC)技术，在nacl - cacl2熔液中进行电化学还原反应，研究了粘土矿物中风化黑云母(WB)的脱除和控制结晶的可能性。循环伏安(CV)测量在+0.5 V至−2.2 V范围内进行。在CV光谱中确认了几个峰。在−1.4 V处的峰表示铁在WB中的还原反应，因此我们在−1.4 V下进行了2 h的还原铁(Fe)实验。通过x射线荧光分析测定EC处理后的Cs去除率，证实Cs去除率几乎为100%。为了了解还原反应的影响，我们进行了x射线吸附精细结构(XAFS)分析。在EC处理前，WB中的铁以fe3 +和fe2 +的混合形式存在。经EC处理后，XAFS分析证实了Fe 2+的存在。基于这一发现，EC处理对WB中铁的还原是有效的。结果表明，Fe 2o3的形成受到抑制，还原反应对晶体的形成有较好的控制作用。

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Electrochemical Cs removal and crystal formation from Fukushima weathered biotite in molten NaCl-CaCl2

The possibility of removal and controlling crystal formation from weathered biotite (WB) in clay minerals were investigated using molten salt electrochemistry (EC) in molten NaCl-CaCl 2 under an electrochemical reductive reaction. Cyclic Voltammogram (CV) measurements were performed in the range of +0.5 V to −2.2 V. Several peaks were confirmed in the CV spectra. The peak at −1.4 V represents a reduction reaction of Fe in WB, so we conducted an experiment at −1.4 V for 2 h to reduce Iron (Fe). The Cs removal rate after EC treatment was determined by X-ray fluorescence analysis, and almost 100% Cs removal was confirmed. To understand the effect of the reductive reaction, we performed X-ray Adsorption Fine Structure (XAFS) analysis. Before EC treatment, the Fe in WB was present as a mixture of Fe 3+ and Fe 2+ . After EC treatment, the presence of Fe 2+ was confirmed by XAFS analysis. Based on this finding, EC treatment is effective for reducing Fe in WB. This result indicated that Fe 2 O 3 formation was suppressed, and the reduction reaction was effective for controlling crystal formation.

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来源期刊

AIMS Electronics and Electrical Engineering Engineering-Control and Systems Engineering

CiteScore

2.40

自引率

0.00%

发文量

审稿时长

8 weeks