Abstract
Thermoelectric materials have been expected as a critical underlying technology for developing an autonomous power generation system driven at near room temperature. For this sake, Fe3Al2Si3 intermetallic compound is a promising candidate, though its high lattice thermal conductivity is a bottleneck toward practical applications. Herein, we have performed the first-principles calculations to clarify the microscopic mechanism of thermal transport and establish effective ways to reduce the lattice thermal conductivity of Fe3Al2Si3. Our calculations show that the lowest-lying optical mode has a significant contribution from Al atom vibration. It should correspond to large thermal displacements Al atoms. However, these behaviors do not directly cause an increase of the 3-phonon scattering rate. The calculated lattice thermal conductivity shows a typical temperature dependence and moderate magnitude. From the calculated thermal conductivity spectrum and cumulative thermal conductivity, we can see that there is much room to reduce the lattice thermal conductivity. We can expect that heavy-element doping on Al site and controlling fine microstructure are effective strategies to decrease the lattice thermal conductivity. This work suggests useful information to manipulate the thermal transport of Fe3Al2Si3, which will make this material closer to practical use.
Highlights
Thermoelectric power generation (TEG) through the direct conversion of waste heat into electrical energy can contribute to a sustainable society when its efficiency dramatically improves
This study focuses on revealing the lattice dynamics and thermal transport mechanism of Fe3 Al2 Si3 and extracting effective ways to reduce its lattice thermal conductivity based on first-principles calculations
From density functional theory (DFT)-based phonon calculations, we have identified a low-energy optical mode lying near acoustic modes which has a dominant contribution from Al atom vibration
Summary
Thermoelectric power generation (TEG) through the direct conversion of waste heat into electrical energy can contribute to a sustainable society when its efficiency dramatically improves. An Fe-Al-Si ternary intermetallic compound Fe3 Al2 Si3 has been considered as a promising candidate of a novel practical thermoelectric material for lowtemperature applications [2,3,4,5,6,7]. The ZT value of Fe3 Al2 Si3 is much lower than any other practical thermoelectric materials, it has some significant advantages: (1) lowcost and non-toxic, (2) high chemical and thermal stabilities, (3) an excellent oxidation resistance, and (4) a good balance of mechanical properties [6,7].
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