Secondary Reduction of Refractory Metal near Smooth Cathode during the Salt Melt Electrolysis. 3. Numerical Reproducing of Natural Experiment with the Nb Cathodic Reduction in KNaCl2–NaF–K3NbF7 Melt

Secondary Reduction of Refractory Metal near Smooth Cathode during the Salt Melt Electrolysis. 3. Numerical Reproducing of Natural Experiment with the Nb Cathodic Reduction in KNaCl2–NaF–K3NbF7 Melt

In terms of the model of steady-state process of a refractory-metal ion secondary reduction with an alkali (or alkali-earth) metal formed on a smooth cathode during salt melt electrolysis, numerical reproducing of a natural experiment is carried out. The model calculations are based on the polarizat...

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Bibliographic Details
Published in:Russian journal of electrochemistry Vol. 56; no. 12; pp. 959 - 968
Main Authors: Khramov, A. P., Chernyshev, A. A., Isakov, A. V., Suzdal’tsev, A. V., Zaykov, Yu. P.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-12-2020
Springer Nature B.V
Subjects:
Cathodes
Cathodic polarization
Chemistry
Chemistry and Materials Science
Constraining
Current density
Diffusion layers
Electrochemistry
Electrode polarization
Electrolysis
Experiments
Mathematical models
Physical Chemistry
Steady state models
Thickness
model of cathode process in alkali-halide melt
model of secondary reduction at the cathode by alkali or alkali-earth metal
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Summary:In terms of the model of steady-state process of a refractory-metal ion secondary reduction with an alkali (or alkali-earth) metal formed on a smooth cathode during salt melt electrolysis, numerical reproducing of a natural experiment is carried out. The model calculations are based on the polarization measured during the cathodic reduction of Nb in chloride―fluoride melt: [Nb] = 2.4 mol %, 800°C, current density i up to 5.4 A/cm 2 . On a smooth cathode in the overvoltage range from 0.21 to 0.41 V ( i = 0.75―1.17 A/cm 2 ), the reduction mechanism is shown to completely change from primary to the secondary reduction. The secondary reduction zone is located inside the diffusion layer and moves away from the cathode with increasing i . Even at maximal i , this zone remains inside δ (δ is the thickness of the diffusion layer): with i = 0.96 A/cm 2 , the coordinate of the maximum of the secondary reduction rate x m = 0; with i = 5.4 A/cm 2 , x m = 0.93δ (in the experiment, the value of i at which x m ≥ δ was not achieved). At i = 5.4 A/cm 2 , the fraction of secondary reduction in the bulk is insignificant, ≈ 10 −5 A/cm 2 . The δ vs. E curve is calculated: when E is shifted from the equilibrium value toward the negative values, | i| increased from zero and higher, whereas δ first decreased by an order of magnitude and then increased. Correspondingly, the limiting diffusion current is not constant at a constant Nb concentration in the bulk. This is the reason of uncertain limiting current on steady-state cathodic polarization curves during the electrolysis of metals in melts. A hypothesis is proposed on the dependence of the Nernst diffusion layer thickness near the cathode on the current density exceeding the limiting diffusion current density under the conditions of secondary reduction.
ISSN:1023-1935
1608-3342
DOI:10.1134/S102319352011004X