2022
DOI: 10.3390/molecules27196567
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Electronic Structure-, Phonon Spectrum-, and Effective Mass- Related Thermoelectric Properties of PdXSn (X = Zr, Hf) Half Heuslers

Abstract: We hereby discuss the thermoelectric properties of PdXSn(X = Zr, Hf) half Heuslers in relation to lattice thermal conductivity probed under effective mass (hole/electrons) calculations and deformation potential theory. In addition, we report the structural, electronic, mechanical, and lattice dynamics of these materials as well. Both alloys are indirect band gap semiconductors with a gap of 0.91 eV and 0.82 eV for PdZrSn and PdHfSn, respectively. Both half Heusler materials are mechanically and dynamically sta… Show more

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Cited by 20 publications
(8 citation statements)
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“…The dimensionless figure of merit (ZT) of HfIrAs at 300 K, 600 K, and 800 K is 0.23, 0.5, and 0.57, respectively (see Figure 4d). The ZTs obtained in this work are comparable to that of a good thermoelectric candidate from previous similar work [78]. The ZT of HfIrAs increases with an increase in temperature, and the ZT of 0.57 shows that HfIrAs is a good thermoelectric material.…”
Section: Thermoelectric Properties Of Hfirassupporting
confidence: 81%
“…The dimensionless figure of merit (ZT) of HfIrAs at 300 K, 600 K, and 800 K is 0.23, 0.5, and 0.57, respectively (see Figure 4d). The ZTs obtained in this work are comparable to that of a good thermoelectric candidate from previous similar work [78]. The ZT of HfIrAs increases with an increase in temperature, and the ZT of 0.57 shows that HfIrAs is a good thermoelectric material.…”
Section: Thermoelectric Properties Of Hfirassupporting
confidence: 81%
“…At a temperature of 400 K, the NbIrSn compound exhibits maximum Seebeck coefficient values of approximately ∼920 μV/K for p-type and ∼755 μV/K for n-type regions within the range of examined chemical potentials. The values mentioned are comparable to those observed in PdXSn (X = Zr, Hf) [73] but lower than those in PtXSn (X = Zr, Hf) [74]. With increasing temperature, the maximum values of the Seebeck coefficient decrease.…”
Section: Thermoelectric Propertiessupporting
confidence: 70%
“…The chemical stability is determined by formation energy that is specified as the difference between the energy of the compound and the sum of energies of the elemental constituents. [37][38][39] ΔE f = [E(Sn 2 SSe) − nE(Sn 2 ) − nE(S) − nE(Se)]∕n (7) where E(Sn 2 SSe), E(Sn 2 ), E(S), and E(Se) are total energy of Sn 2 SSe, Sn 2 , S, and Se, respectively. The computed value of formation energy is −1.684.…”
Section: Resultsmentioning
confidence: 99%
“…The chemical stability is determined by formation energy that is specified as the difference between the energy of the compound and the sum of energies of the elemental constituents. [ 37–39 ] normalΔEfbadbreak=[Efalse(Sn2SSefalse)nEfalse(Sn2false)nEfalse(Sfalse)nEfalse(Sefalse)]/n$$\begin{equation} \Delta E_f =[E(Sn_{2}SSe)-nE(Sn_{2})-nE(S)-nE(Se)]/n \end{equation}$$where E(Sn2SSe$Sn_{2}SSe$), E(Sn2$Sn_{2}$), E(S), and E(Se) are total energy of Sn2SSe$Sn_{2}SSe$, Sn2$Sn_{2}$, S, and Se, respectively. The computed value of formation energy is −1.684.…”
Section: Resultsmentioning
confidence: 99%