Phase Equilibria and Thermodynamic Properties of Selected Compounds in the Ag-Ga-Te-AgBr System

Mykola Moroz; Fiseha Tesfaye; Pavlo Demchenko; Myroslava Prokhorenko; Emanuela  Mastronardo; Oleksandr Reshetnyak; Daniel Lindberg; Leena Hupa

doi:10.1007/s11669-024-01095-x

Phase Equilibria and Thermodynamic Properties of Selected Compounds in the Ag-Ga-Te-AgBr System

Mykola Moroz^*
, Fiseha Tesfaye
, Pavlo Demchenko
, Myroslava Prokhorenko
, Emanuela Mastronardo
, Oleksandr Reshetnyak
, Daniel Lindberg
, Leena Hupa

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

3 Citations (Scopus)

82 Downloads (Pure)

Abstract

The equilibrium T − x space of the Ag-Ga-Te-AgBr system in the part Ag2Te-GaTe-Te-AgBr-Ag2Te below 600 K has been divided into separate phase regions using the electromotive force (EMF) method. Accurate experimental data were obtained using the following electrochemical cells (ECs): (−) IE | NE | SSE | R{Ag+} | PE | IE (+), where IE is the inert electrode (graphite powder), NE is the negative electrode (silver powder), SSE is the solid-state electrolyte (glassy Ag3GeS3Br), PE is the positive electrode, R{Ag+} is the region of PE that is contact in with SSE. At the stage of cell preparation, PE is a non-equilibrium phase mixture of the well-mixed powdered compounds Ag2Te, GaTe, Ga2Te3, AgBr, and tellurium, taken in ratios corresponding to two or three different points of interest for each of the phase regions. The equilibrium set of phases was formed in the R{Ag+} region at 600 K for 48 h with the participation of the Ag+ ions. Silver cations, displaced for thermodynamic reasons from the NE to the PE of ECs, acted as catalysts, i.e., small nucleation centers of equilibrium phases. The spatial position of the established phase regions relative to the position of silver was used to express the overall reactions of synthesis of the binary Ga2Te5, Ga7Te10, Ga3Te4, ternary AgGa5Te8, and quaternary Ag3Ga10Te16Br, Ag3Ga2Te4Br, Ag27Ga2Te12Br9 compounds in the PE of ECs. The values of the standard thermodynamic functions (Gibbs energies, enthalpies, and entropies) of these compounds were determined based on the temperature dependencies of the EMF of the ECs.

Original language	English
Pages (from-to)	447-458
Number of pages	12
Journal	Journal of Phase Equilibria and Diffusion
Volume	45
Issue number	3
DOIs	https://doi.org/10.1007/s11669-024-01095-x
Publication status	Published - Jun 2024
MoE publication type	A1 Journal article-refereed

Funding

The present work was financed partially by the grant of the Ministry of Education and Science of Ukraine No. 0123U101857 “Physico-chemistry of functional nanomaterials for electrochemical systems”, international projects: #HX-010123 from ‘‘Materials Phases Data System, Viznau, Switzerland’’ and the Simons Foundation (Award Number: 1037973). This work was partly funded by the K.H. Renlund Foundation under the project “Innovative e-waste recycling processes for greener and more efficient recoveries of critical metals and energy” at Åbo Akademi University.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 11 Sustainable Cities and Communities

Keywords

EMF method
Gibbs energy
phase equilibria
thermoelectric materials
thermodynamic properties

Access to Document

10.1007/s11669-024-01095-x

Accepted version_JPED-23-09-2786.R2Accepted author manuscript, 1.18 MBLicence: All rights reserved

https://urn.fi/URN:NBN:fi-fe2025022413356

Innovative e-waste recycling processes for greener and more efficient recoveries of critical metals and energy
Tesfaye, F. (Principal Investigator), Vainio, E. (Co-Principal Investigator), Hupa, L. (Co-Investigator) & Jylhävuori, N. (Co-Investigator)
01/01/22 → 31/12/23
Project: Foundation

Cite this

@article{f592dad50746440b8f6cafc9d0bf7e5c,

title = "Phase Equilibria and Thermodynamic Properties of Selected Compounds in the Ag-Ga-Te-AgBr System",

abstract = "The equilibrium T − x space of the Ag-Ga-Te-AgBr system in the part Ag2Te-GaTe-Te-AgBr-Ag2Te below 600 K has been divided into separate phase regions using the electromotive force (EMF) method. Accurate experimental data were obtained using the following electrochemical cells (ECs): (−) IE | NE | SSE | R\{Ag+\} | PE | IE (+), where IE is the inert electrode (graphite powder), NE is the negative electrode (silver powder), SSE is the solid-state electrolyte (glassy Ag3GeS3Br), PE is the positive electrode, R\{Ag+\} is the region of PE that is contact in with SSE. At the stage of cell preparation, PE is a non-equilibrium phase mixture of the well-mixed powdered compounds Ag2Te, GaTe, Ga2Te3, AgBr, and tellurium, taken in ratios corresponding to two or three different points of interest for each of the phase regions. The equilibrium set of phases was formed in the R\{Ag+\} region at 600 K for 48 h with the participation of the Ag+ ions. Silver cations, displaced for thermodynamic reasons from the NE to the PE of ECs, acted as catalysts, i.e., small nucleation centers of equilibrium phases. The spatial position of the established phase regions relative to the position of silver was used to express the overall reactions of synthesis of the binary Ga2Te5, Ga7Te10, Ga3Te4, ternary AgGa5Te8, and quaternary Ag3Ga10Te16Br, Ag3Ga2Te4Br, Ag27Ga2Te12Br9 compounds in the PE of ECs. The values of the standard thermodynamic functions (Gibbs energies, enthalpies, and entropies) of these compounds were determined based on the temperature dependencies of the EMF of the ECs.",

keywords = "EMF method, Gibbs energy, phase equilibria, thermoelectric materials, thermodynamic properties",

author = "Mykola Moroz and Fiseha Tesfaye and Pavlo Demchenko and Myroslava Prokhorenko and Emanuela Mastronardo and Oleksandr Reshetnyak and Daniel Lindberg and Leena Hupa",

year = "2024",

month = jun,

doi = "10.1007/s11669-024-01095-x",

language = "English",

volume = "45",

pages = "447--458",

journal = "Journal of Phase Equilibria and Diffusion",

issn = "1547-7037",

publisher = "Springer",

number = "3",

}

TY - JOUR

T1 - Phase Equilibria and Thermodynamic Properties of Selected Compounds in the Ag-Ga-Te-AgBr System

AU - Moroz, Mykola

AU - Tesfaye, Fiseha

AU - Demchenko, Pavlo

AU - Prokhorenko, Myroslava

AU - Mastronardo, Emanuela

AU - Reshetnyak, Oleksandr

AU - Lindberg, Daniel

AU - Hupa, Leena

PY - 2024/6

Y1 - 2024/6

N2 - The equilibrium T − x space of the Ag-Ga-Te-AgBr system in the part Ag2Te-GaTe-Te-AgBr-Ag2Te below 600 K has been divided into separate phase regions using the electromotive force (EMF) method. Accurate experimental data were obtained using the following electrochemical cells (ECs): (−) IE | NE | SSE | R{Ag+} | PE | IE (+), where IE is the inert electrode (graphite powder), NE is the negative electrode (silver powder), SSE is the solid-state electrolyte (glassy Ag3GeS3Br), PE is the positive electrode, R{Ag+} is the region of PE that is contact in with SSE. At the stage of cell preparation, PE is a non-equilibrium phase mixture of the well-mixed powdered compounds Ag2Te, GaTe, Ga2Te3, AgBr, and tellurium, taken in ratios corresponding to two or three different points of interest for each of the phase regions. The equilibrium set of phases was formed in the R{Ag+} region at 600 K for 48 h with the participation of the Ag+ ions. Silver cations, displaced for thermodynamic reasons from the NE to the PE of ECs, acted as catalysts, i.e., small nucleation centers of equilibrium phases. The spatial position of the established phase regions relative to the position of silver was used to express the overall reactions of synthesis of the binary Ga2Te5, Ga7Te10, Ga3Te4, ternary AgGa5Te8, and quaternary Ag3Ga10Te16Br, Ag3Ga2Te4Br, Ag27Ga2Te12Br9 compounds in the PE of ECs. The values of the standard thermodynamic functions (Gibbs energies, enthalpies, and entropies) of these compounds were determined based on the temperature dependencies of the EMF of the ECs.

AB - The equilibrium T − x space of the Ag-Ga-Te-AgBr system in the part Ag2Te-GaTe-Te-AgBr-Ag2Te below 600 K has been divided into separate phase regions using the electromotive force (EMF) method. Accurate experimental data were obtained using the following electrochemical cells (ECs): (−) IE | NE | SSE | R{Ag+} | PE | IE (+), where IE is the inert electrode (graphite powder), NE is the negative electrode (silver powder), SSE is the solid-state electrolyte (glassy Ag3GeS3Br), PE is the positive electrode, R{Ag+} is the region of PE that is contact in with SSE. At the stage of cell preparation, PE is a non-equilibrium phase mixture of the well-mixed powdered compounds Ag2Te, GaTe, Ga2Te3, AgBr, and tellurium, taken in ratios corresponding to two or three different points of interest for each of the phase regions. The equilibrium set of phases was formed in the R{Ag+} region at 600 K for 48 h with the participation of the Ag+ ions. Silver cations, displaced for thermodynamic reasons from the NE to the PE of ECs, acted as catalysts, i.e., small nucleation centers of equilibrium phases. The spatial position of the established phase regions relative to the position of silver was used to express the overall reactions of synthesis of the binary Ga2Te5, Ga7Te10, Ga3Te4, ternary AgGa5Te8, and quaternary Ag3Ga10Te16Br, Ag3Ga2Te4Br, Ag27Ga2Te12Br9 compounds in the PE of ECs. The values of the standard thermodynamic functions (Gibbs energies, enthalpies, and entropies) of these compounds were determined based on the temperature dependencies of the EMF of the ECs.

KW - EMF method

KW - Gibbs energy

KW - phase equilibria

KW - thermoelectric materials

KW - thermodynamic properties

U2 - 10.1007/s11669-024-01095-x

DO - 10.1007/s11669-024-01095-x

M3 - Article

SN - 1547-7037

VL - 45

SP - 447

EP - 458

JO - Journal of Phase Equilibria and Diffusion

JF - Journal of Phase Equilibria and Diffusion

IS - 3

ER -

Phase Equilibria and Thermodynamic Properties of Selected Compounds in the Ag-Ga-Te-AgBr System

Abstract

Funding

UN SDGs

Keywords

Access to Document

Fingerprint

Projects

Innovative e-waste recycling processes for greener and more efficient recoveries of critical metals and energy

Cite this