Research progress in development and processing of rare earths may be described following [13, 14]. Density of a typical metal as a function of concentration and temperature is presented by following equation.
𝜌 = −6.53212 × 10−4𝑐2 − 0.06987𝑐 + 1.31265 × 10−5𝑇2 − 0.05297𝑇 + 1.69004 × 10−4𝑐𝑇+ 43.14013
Solubility and dissolution of rare earth oxide in the fluoride melt [15]
Rare earths in their oxide forms may exhibit solubility and may be dissolved in their oxide and fluoride electrolyte melts.
Nd2O3 solubility in fluoride melts with different NdF3-LiF compositions and at different temperatures [15].
Production of Nd-Fe foundry alloy by the electrolysis of neodymium fluoride
During the electrolysis of these melts at the electrodes the following reactions are taking place: at the graphite anode. [16]
at the iron cathode:
Production of Nd-Fe foundry alloy by the electrolysis of neodymium oxide
During the electrolysis of neodymium oxide in fluoride melts at the electrodes the following reactions are taking place at the graphite anode [16]
at the iron cathode:
Coefficients
Following coefficients are important, must be considered and calculated for effective electrometallurgical operations. Activity coefficients, diffusion coefficients, equilibrium separation coefficients, effective separation coefficients.
Vapor pressure
Cell efficiency
Cell efficiency may be calculated by measuring the concentration of reactant and product species in electrolyte. An excellent study documents these in Cerium [18]. Interested reader is referred to it for further details.
Mass transfer
Mass transfer coefficients, solubility of rare earth oxides in molten fluorides, oxide solubility determinations, oxide solubility diagrams. Prior to the proper oxide solubility determinations and diagram development, the equilibration time for oxide source dissolution, e.g., Dy2O3 and Dy2(CO3)3, was determined. It was determined by adding a certain amount of the oxide source (below solubility limit) and sample analysis thereafter at certain intervals. The time of equilibrium dissolution is measured by noting time at which the analyzed oxide content becomes constant. Below figures (Fig – 5) show the results obtained when Dy2O3 was added to the DyF3-LiF melts at different compositions, i.e., DyF3 (50 mol pct)-LiF (50 mol pct) and DyF3 (20 mol pct)-LiF (80 mol pct), at a working temperature of 1323 K (1050 C). The results showed that in the case of the eutectic composition longer dissolution times than in the equimolar composition are needed, in which case, all Dy2O3 added is dissolved well within 30 minutes.
Diagrams for electrodeposition of Nd from its salts are described below [19]