Raveena Gupta scite author profile

Several ternary “Janus” metal dichalcogenides such as {Mo,Zr,Pt}-SSe have emerged as candidates with significant potential for optoelectronic, piezoelectric, and thermoelectric applications. SnSSe, a natural option to explore as a thermoelectric given that its “parent” structures are SnS 2 and SnSe 2 has, however, only recently been shown to be mechanically stable. Here, we calculate the lattice thermal conductivities of the Janus SnSSe monolayer along with those of its parent dicalchogenides. The phonon frequencies of SnSSe are intermediate between those of SnSe 2 and SnS 2 ; however, its thermal conductivity is the lowest of the three and even lower than that of a random Sn[S 0.5 Se 0.5 ] 2 alloy. This can be attributed to the breakdown of inversion symmetry and manifests as a subtle effect beyond the reach of the relaxation-time approximation. Together with its low favorable power factor, its thermal conductivity confirms SnSSe as a good candidate for thermoelectric applications.

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Thermoelectric properties of the SnS monolayer: Fully ab initio and accelerated calculations

Gupta

Dongre

Carrete

et al. 2021

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An energetic and dynamical stability analysis of five candidate structures—hexagonal, buckled hexagonal, litharge, inverted litharge, and distorted-NaCl—of the SnS monolayer is performed using density functional theory. The most stable is found to be a highly distorted-NaCl-type structure. The thermoelectric properties of this monolayer are then calculated using the density functional theory and the Boltzmann transport equation. In terms of phonon scattering, there is a sharp contrast between this monolayer and bulk materials, where normal processes are more important. The calculations reveal that the SnS monolayer has enhanced electrical performance as compared to the bulk phase. As a consequence, high figures of merit ZT∼5 and ZT∼1.36 are predicted at 600 and 300 K, respectively, for the monolayer, ∼33 times higher than the ZT of its bulk analog. Therefore, this structure is an interesting candidate for room-temperature thermoelectric applications. A comparison between the fully ab initio results and simpler models based on relaxation times for electrons and phonons highlights the efficiency of computationally inexpensive models. However, ab initio calculations are found to be very important for the prediction of thermal transport properties.

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Theoretical model for predicting thermoelectric properties of tin chalcogenides

Gupta

Kumar

Kaur

et al. 2020

Phys. Chem. Chem. Phys.

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A theoretical model of the thermoelectric properties of SnSxSe1−x and how to further enhance its thermoelectric performance

Gupta

Kaur

Carrete

et al. 2019

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Tin-based chalcogenides have a lot of potential as thermoelectric materials due to their ultralow thermal conductivity. Therefore, most reports on doped SnS focus on its power factor as the other condition for a high thermoelectric figure of merit (ZT). Here, we use the Boltzmann transport formalism to calculate both the power factor and the thermal conductivity for SnS, SnSe, and SnSxSe1−x and compare it with experimental measurements. Our theoretical model, based on a relaxation-time formalism, is in very good agreement with the reported values. We conclude that, while impurity scattering plays a major role in electron transport and, therefore, largely determines the power factor, alloy scattering is crucial for phonon transport. Specifically, alloying reduces the thermal conductivity of SnSe0.70S0.30 by a factor of ∼1.3 compared to SnSe and by a factor of ∼2 compared to SnS. This leads to ∼65% and ∼33% enhancements of ZT for p-type and n-type doping, respectively, at 800 K with respect to SnSe.

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Raveena Gupta

The Effect of Janus Asymmetry on Thermal Transport in SnSSe

Thermoelectric properties of the SnS monolayer: Fully ab initio and accelerated calculations

Theoretical model for predicting thermoelectric properties of tin chalcogenides

A theoretical model of the thermoelectric properties of SnSxSe1−x and how to further enhance its thermoelectric performance

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