Abstract
Thermal stabilities of selected ternary phases of industrial interest in the Ag-Cu-S system have been studied by the calorimetric and electromotive force techniques. The ternary compounds Ag1.2Cu0.8S (mineral mackinstryite) and AgCuS (mineral stromeyerite) were equilibrated through high-temperature reaction of the pure Cu2S and Ag2S in an inert atmosphere. The synthesized single solid sample constituting the two ternary phases was ground into fine powders and lightly pressed into pellets before calorimetric measurements. An electrochemical cell incorporating the two equilibrated phase and additional CuS as a cathode material was employed. The measurement results obtained with both techniques were analyzed and thermodynamic properties in the system have been determined and compared with the available literature values. Enthalpy of fusion data of the Ag-richer solid solution (Ag,Cu)2S have also been determined directly from the experimental data for the first time. The thermodynamic quantities determined in this work can be used to calculate thermal energy of processes involving the Ag-Cu-S-ternary phases. By applying the obtained results and the critically evaluated literature data, we have developed a thermodynamic database. The self-developed database was combined with the latest pure substances database of the FactSage software package to model the phase diagram of the Ag2S-Cu2S system.
Highlights
Received: 8 December 2021Today, the complexities and low grade of the available raw materials from ore deposits are challenging the production of high-grade metals by the conventional metallurgical processes
The differential scanning calorimetry (DSC)-thermal gravimetric analysis (TGA) measurements were conducted for the equilibrated two-phase sample (Ag1.2 Cu0.8 S and AgCuS) in this work
On the heating DSC curve, phase transitions and melting temperatures appeared as endothermic peaks
Summary
The complexities and low grade of the available raw materials from ore deposits are challenging the production of high-grade metals by the conventional metallurgical processes. To address this issue, metallurgists are considering alternatives strategies and modify operating flow sheets for processing more complex feedstock in an energy efficient, environmentally friendly and economically sound way. The overall result of these efforts will eventually contribute to create adaptive and dynamic metallurgical processes, including roasting as a thermal pretreatment that enriches raw materials and extracts thermal energy.
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