Thermodynamic Effect of NaCl and KCl Addition on the Equilibrium Between Molten ZnCl2-Based Salt and Liquid Zn-Cd Alloy

Purification of molten salt is essential for producing highly pure metal from melts by chemical reactions and electrolysis. Cementation is a technique used for refining molten ZnCl2-based salt. In this study, we investigated the thermodynamics involved in the reduction of CdCl2 in molten ZnCl2-based salt with Zn metal to optimize the separation conditions for Cd; this is difficult as both Cd and Zn have similar electrochemical potentials. We experimentally investigated the thermodynamic equilibrium between the molten ZnCl2-based salt and liquid Zn-Cd alloy at 723 K (450 degrees C). The equilibrium concentration of CdCl2 in 40 mol pct ZnCl2-NaCl-KCl coexisting with Zn-Cd alloy changed as the ratio of NaCl and KCl was altered. The activity coefficient of CdCl2 in the system at 723 K (450 degrees C) was obtained with the calculated activity coefficient of ZnCl2 using several thermodynamic solution models. A two-step cementation process was used to demonstrate the possibility of lowering the concentration of Cd. The Cd content in molten salt was lowered to - 10 mass ppm by the two-step reaction, and the feasibility of multi-step cementation was demonstrated.

Automated summary

The study investigated the thermodynamics of reducing CdCl2 in molten salt with Zn metal and optimizing the separation conditions for Cd; the equilibrium concentration of CdCl2 in ZnCl2-NaCl-KCl changed with the ratio of NaCl and KCl; a two-step cementation process successfully lowered Cd concentration in molten salt.