Abstract
The viability of Si-Ge alloys in thermoelectric applications lies in its high figure-of-merit, non-toxicity and earth-abundance. However, what restricts its wider acceptance is its operation temperature (above 1000 K) which is primarily due to its electronic band gap. By means of density functional theory calculations, we propose that iso-electronic Sn substitutions in Si-Ge can not only lower its operation to mid-temperature range but also deliver a high thermoelectric performance. While calculations find a near invariance in the magnitude of thermopower, empirical models indicate that the materials thermal conductivity would also reduce, thereby substantiating that Si-Ge-Sn alloys are promising mid-temperature thermoelectrics.
Highlights
The viability of Si-Ge alloys in thermoelectric applications lies in its high figureof-merit, non-toxicity and earth-abundance
By means of density functional theory calculations, we propose that iso-electronic Sn substitutions in Si-Ge can lower its operation to mid-temperature range and deliver a high thermoelectric performance
While calculations find a near invariance in the magnitude of thermopower, empirical models indicate that the materials thermal conductivity would reduce, thereby substantiating that Si-Ge-Sn alloys are promising mid-temperature thermoelectrics
Summary
The viability of Si-Ge alloys in thermoelectric applications lies in its high figureof-merit, non-toxicity and earth-abundance. Band gap engineering of Si-Ge alloys for mid-temperature thermoelectric applications By means of density functional theory calculations, we propose that iso-electronic Sn substitutions in Si-Ge can lower its operation to mid-temperature range and deliver a high thermoelectric performance.
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