Selective Permeation of Dysprosium Through an Alloy Diaphragm in Molten Chloride Systems

Oishi, Tadashi; Yaguchi, Miki; Katasho, Yumi; Konishi, Hisatoshi

doi:10.1149/1945-7111/abd0cc

Cited by 9 publications

(25 citation statements)

References 16 publications

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“…During electrolysis, RE ions were oxidized and dissolved in the anode chamber, and specific RE element alloys were formed, which diffused through the IG diaphragm; finally, the RE metal was recovered at the cathode. Our previous studies confirmed that RE-Ni alloys (RE = Pr, Nd, Dy) are selectively formed via electrolysis by utilizing Ni-based substrates in the following molten electrolytes: LiCl-KCl-RECl 3 at 723 K, [12][13][14][15][16] NaCl-KCl-RECl 3 at 973 K, [17][18][19][20] and LiF-CaF 2 -REF 3 at 1123 K. 19,[21][22][23][24][25] In addition, this process exhibits a high RE separation ability over a specific potential range. However, the brittle nature of RE-Ni alloys results in durability issues in the alloy diaphragms.…”

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confidence: 62%

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF₂-NdF₃

Kawaguchi

2021

J. Electrochem. Soc.

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In the present study, as a fundamental study for recycling Nd from Nd-Fe-B permanent magnet scrap, the electrochemical Nd-alloying behavior of Fe was investigated in a molten LiF-CaF2-NdF3 (0.3 or 0.5 mol%) system at 1123 K. Herein, the equilibrium potential of Nd3+/Nd was determined as 0.18 V (vs Li+/Li) by open-circuit potentiometry using a Mo electrode. Cyclic voltammetry and open-circuit potentiometry were conducted using an Fe electrode, and the results suggested the formation of multiple phases within the Nd-Fe alloys. Alloy samples were prepared via one- or two-step potentiostatic electrolysis of Fe electrodes at various potentials. The formation of liquid Nd-Fe alloy was confirmed through one-step potentiostatic electrolysis at 0.10 V. The solid Nd2Fe17 alloy was formed via a two-step potentiostatic electrolysis, wherein the potential was changed to 0.25 V after the initial electrolysis at 0.10 V, indicating that the Nd2Fe17 phase is thermodynamically stable at 0.25 V. The equilibrium potentials of the coexistence states of liq. Nd-Fe + Nd2Fe17 and Nd2Fe17 + Fe were determined as 0.19 and 0.31 V, respectively, which are in good agreement with the previously reported thermodynamic data.

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confidence: 62%

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF₂-NdF₃

Kawaguchi

2021

J. Electrochem. Soc.

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“…14 Therefore, in our ongoing research on selective permeation through an alloy diaphragm, we have been most intensively investigating Ni and Ni-based alloys. [7][8][9][10][11][12][13] Recently, we reported selective permeation of Dy through an RE-Ni alloy diaphragm in molten LiCl-KCl eutectic melts containing NdCl 3 and DyCl 3 at 450 °C. 12 However, selective permeation of Nd is indispensable for realizing the recycling process shown in Fig.…”

Section: Re Anolytementioning

confidence: 99%

“…1). [7][8][9][10][11][12][13] This process entails the use of RE-IG (IG = Fe, Ni, and Co) alloy diaphragms for the separation of the REs in molten salts. 7 The RE-IG alloy diaphragm acts as a bipolar electrode and RE ions permeate through three steps: (a) reduction of the RE ions to form an alloy on the anolyte side of the diaphragm according to reaction 1, (b) transportation of RE atoms in the diaphragm, and (c) oxidation of the RE atoms that dissolve into the catholyte as RE ions on the other side of the diaphragm according to reaction 2.…”

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confidence: 99%

Selective Permeation of Neodymium Through an Alloy Diaphragm in Molten Chloride Systems

Oishi¹,

Yaguchi²,

Katasho³

2021

J. Electrochem. Soc.

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The selective permeation of Nd through an RE–Ni (RE = Nd and Dy) alloy diaphragm was investigated in LiCl–KCl eutectic melts containing NdCl3 and DyCl3 or LaCl3 at 450 °C. The investigation was a part of an ongoing study on a new recycling process for Nd–Fe–B permanent magnets. Selective permeation of Nd was achieved by controlling the potential of the alloy diaphragm, which functioned as a bipolar electrode. Interestingly, energy dispersive X-ray analysis revealed that the Nd content in the alloy diaphragm was less than 2 at%. These results suggest that the transportation rate of Nd atoms in the alloy diaphragm was extremely high compared to that of Dy atoms. To obtain further insights into the transportation mechanism of the RE atoms in the alloy diaphragm, transmission electron microscopy (TEM) was performed. The TEM results suggest that the transportation of RE atoms cannot be explained only by simple grain boundary diffusion, and that a large number of dislocations formed in the alloy diaphragm contribute to the rapid transportation of the RE atoms.

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“…Thus, it is necessary to develop an inexpensive and effective recovery/separation process of Dy from scraps of the Dy-added Nd-Fe-B magnet. From this background, we have been investigating a new recovery process of Dy and Nd from the magnet scraps using molten salt electrolysis and alloy diaphragms (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14). The key step in this process is the alloying and de-alloying of rare earth (RE) elements on both sides of the diaphragm in order to effectively separate them in the molten salt.…”

Section: Introductionmentioning

confidence: 99%

240th ECS Meeting (Hirokazu Konishi)

Konishi¹

2021

Preprint

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The electrochemical formation of Dy-Ni alloys was investigated in a molten CsCl-DyCl3 system at 973 K under a dry Ar gas atmosphere. Open-circuit potentiometry was performed with a Ni electrode after depositing Dy metal at 0.13 V(vs. Cs+/Cs) for 60 s. Five potential plateaus were observed at 0.34 V, 0.44 V, 0.54 V, 0.79 V and 0.91 V, which were considered to correspond to the potentials of two-phase coexisting states of different Dy–Ni alloys. Potentiostatic electrolysis was conducted at 0.31 V for 4 h and 0.41 V for 1 h using Ni plate electrodes, and XRD analysis indicated the formation of DyNi and DyNi2, respectively. After the formation of DyNi2 on the Ni plate electrodes, potentiostatic electrolysis were also conducted at 075 V and 0.85 V for 1 h. The formed DyNi2 was transformed to Dy2Ni7 and DyNi5 at 0.75 V, while DyNi5 was formed at 0.85 V.

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Selective Permeation of Dysprosium Through an Alloy Diaphragm in Molten Chloride Systems

Cited by 9 publications

References 16 publications

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF₂-NdF₃

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF₂-NdF₃

Selective Permeation of Neodymium Through an Alloy Diaphragm in Molten Chloride Systems

240th ECS Meeting (Hirokazu Konishi)

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Selective Permeation of Dysprosium Through an Alloy Diaphragm in Molten Chloride Systems

Cited by 9 publications

References 16 publications

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF2-NdF3

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF2-NdF3

Selective Permeation of Neodymium Through an Alloy Diaphragm in Molten Chloride Systems

240th ECS Meeting (Hirokazu Konishi)

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Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF₂-NdF₃

Electrochemical Formation of Nd-Fe Alloys in Molten LiF-CaF₂-NdF₃