Abstract
Equilibrium phase formations below 600 K in the parts Ag2Te–FeTe2–F1.12Te–Ag2Te and Ag8GeTe6–GeTe–FeTe2–AgFeTe2–Ag8GeTe6 of the Fe–Ag–Ge–Te system were established by the electromotive force (EMF) method. The positions of 3- and 4-phase regions relative to the composition of silver were applied to express the potential reactions involving the AgFeTe2, Ag2FeTe2, and Ag2FeGeTe4 compounds. The equilibrium synthesis of the set of phases was performed inside positive electrodes (PE) of the electrochemical cells: (−)Graphite ‖LE‖ Fast Ag+ conducting solid-electrolyte ‖R[Ag+]‖PE‖ Graphite(+), where LE is the left (negative) electrode, and R[Ag+] is the buffer region for the diffusion of Ag+ ions into the PE. From the observed results, thermodynamic quantities of AgFeTe2, Ag2FeTe2, and Ag2FeGeTe4 were experimentally determined for the first time. The reliability of the division of the Ag2Te–FeTe2–F1.12Te–Ag2Te and Ag8GeTe6–GeTe–FeTe2–AgFeTe2–Ag8GeTe6 phase regions was confirmed by the calculated thermodynamic quantities of AgFeTe2, Ag2FeTe2, and Ag2FeGeTe4 in equilibrium with phases in the adjacent phase regions. Particularly, the calculated Gibbs energies of Ag2FeGeTe4 in two different adjacent 4-phase regions are consistent, which also indicates that it has stoichiometric composition.
Highlights
Several household devices and industrial applications dissipate considerable amounts of heat
Synthesis of the equilibrium set of phases in solid-state, including the AgFeTe2, Ag2 FeTe2, and Ag2 FeGeTe4 compounds, was conducted in the positive electrodes of electrochemical cell (ECC)
Ag+ cations that shifted from the negative to positive electrode were serving as the nucleation centers for formation of stable compounds and catalysts for the synthesis of the equilibrium set of phases
Summary
Several household devices and industrial applications dissipate considerable amounts of heat. About 60% of the dissipated heat is below 473 K, recovering the low temperature waste heat plays a crucial role in improving energy efficiency [1]. Low and intermediate temperature thermoelectric materials (TMs) technology promoting high performance and low materials cost play a key role for enabling energy efficiency through waste heat harvest and utilization [1,2,3]. Discovery of new functional materials with unique physicochemical properties and a wider thermal stability ranges is one of the main objectives of inorganic materials research. In this regard, ternary and quaternary silver tellurides are good candidate functional materials with unique thermoelectric, photoelectric, non-linear optical, etc.
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