In the present research on rare earth extraction from rare earth oxides (REOs), conversion of rare earth oxides into rare earth fluorides with fluoride fluxes is investigated in order to overcome the problem of low solubility of the rare earth oxides in molten fluoride salts as well as the formation of oxyfluorides in the fluorination process. Based on thermodynamic calculations, a series of experiments were performed for converting the rare earth oxides into rare earth fluorides using AlF 3 , ZnF 2 , FeF 3 , and Na 3 AlF 6 as fluorinating agents in a LiF-Nd 2 O 3 system. The formation of neodymium fluoride as a result of the reactions between these fluxes and neodymium oxide is confirmed. The rare earth fluoride thus formed can subsequently be processed through the electrolysis route in the same reactor, and rare earth metal can be produced as the cathodic deposit. In this concept, the REO dissolution in molten fluorides would become unnecessary due to the complete conversion of the oxide into the fluoride, REF 3 . The results of XRD and EPMA analysis of the reacted samples indicate that AlF 3 , ZnF 2 , and FeF 3 can act as strong fluorinating agents for the neodymium oxide giving rise to a complete conversion of neodymium oxide into neodymium fluoride.
In the present work, selective extraction of rare earth (RE) metals from NdFeB magnets is investigated by studying the effects of various uxes, viz. AlF 3 , ZnF 2 , FeF 3 and Na 3 AlF 6 in the LiF-NdFeB system. The aim is to convert RE from RE magnet into the uoride salt melt. The results show the complete selective separation of neodymium (also dysprosium) from the magnet and formation of rare earth uoride, leaving iron and boron unreacted. The formed rare earth uoride can subsequently be processed in the same reactor through an electrolysis route so that RE can be deposited as a cathode product. The results of XRD and EPMA analysis of the reacted samples indicate that AlF 3 , ZnF 2 and FeF 3 can act as strong uorinating agents for extraction of rare earth from NdFeB magnet, converting the RE to REF 3 .The results con rm the feasibility of the rare earth metals recovery from scrap NdFeB magnet as raw material. The uoride conversion-electrolysis route suggested in the present work enables the extraction of rare earth metals in a single step using the above-mentioned uxes.
The present paper deals with the feasibility of the neodymium recovery from spent Nd-Fe-B magnets using molten salt electrodeposition method. The salt bath consisted of a mixture of LiCl-KCl-NaCl corresponding to the eutectic composition. The experimental set-up with its salient features is presented. AlCl 3 was used as flux and graphite rods dipped in the salt bath served as electrodes. The voltage for the electrolysis was chosen on the basis of the decomposition potential of NdCl 3 . The reaction sequence can be described asIron-free neodymium deposition could be carried out successfully. In view of the proximity of the electrode potentials, the co-deposition of the aluminium and neodymium was observed to occur at the cathode, as revealed by SEM/EDS and XRD analyses of the electrodeposit.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.