First-principles calculation of lattice thermal conductivity in crystalline phase change materials: GeTe, 
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Campi, Davide; Paulatto, Lorenzo; Fugallo, Giorgia; Mauri, Francesco; Bernasconi, Marco

doi:10.1103/physrevb.95.024311

Cited by 109 publications

(110 citation statements)

References 57 publications

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“…In this work we have not included long-range dispersion forces; instead, we have chosen to use PBESol exchange-correlation functional to improve accuracy on the lattice parameters. It has been shown that negative frequencies reported for GST225 become positive once the overestimation of the c parameter is reduced closer to experimental values [31]. Here we report that the use of the PBEsol xc functional improves the agreement of lattice parameters of GST225 with respect to experimental measures, which leads to similar results as those obtained by Campi et al through van der Waals interactions [31].…”

Section: (Gete) 1 (Sb 2 Te 3 ) (Gst124)supporting

confidence: 78%

“…It has been shown that negative frequencies reported for GST225 become positive once the overestimation of the c parameter is reduced closer to experimental values [31]. Here we report that the use of the PBEsol xc functional improves the agreement of lattice parameters of GST225 with respect to experimental measures, which leads to similar results as those obtained by Campi et al through van der Waals interactions [31]. Table II summarizes our relaxed structure parameters together with the available experimental data.…”

Section: (Gete) 1 (Sb 2 Te 3 ) (Gst124)supporting

confidence: 77%

“…8(c). It has been shown that the overestimation of the lattice thermal conductivity obtained from ab initio calculations can be overcome by the inclusion of an effective disorder on the cation masses [31]. The overestimation was expected since, experimentally, there are many other different sources of scattering that we do not take into account in our calculations.…”

Section: (Gete) 2 (Sb 2 Te 3 ) (Gst225)mentioning

confidence: 78%

“…In these PDOS, the states increase almost linearly up to 33 cm −1 and the maximum is reached around 100 cm −1 . As we mentioned before, Campi et al [31] show that the inclusion of vdW corrections in GST225 leads to only positive phonons at the point. In comparison with our results, the negative frequency shown in the mentioned work was around 30 cm −1 .…”

Section: (Gete) 1 (Sb 2 Te 3 ) (Gst124)mentioning

confidence: 84%

“…[50]. Phonon band structure has been reported for some of these structures in the works of Campi et al [31,51].…”

Section: (Gete) 2 (Sb 2 Te 3 ) (Gst225)mentioning

confidence: 95%

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Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)
Ibarra-Hernández
¹
,
Raty
²

2018
Phys. Rev. B

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We use ab initio density functional theory calculations to understand the electronic, dynamical, and thermoelectric behavior of layered crystalline phase-change materials. We perform calculations on the pseudobinary compounds (GeTe) x /(Sb 2 Te 3 ) (GST) with x = 1, 2, and 3. Since the stable configuration of these compounds remains somehow unsettled, we study one stacking configuration for GST124 (x = 1), three for GST225 (x = 2), and two for GST326 (x = 3). A supercell approach is used to check the dynamical stability of the systems while thermoelectric properties are obtained by solving the Boltzmann transport equation. We report that the most accepted stacking configuration of GST124, GST225, and GST326 have metallic character and for the case of x = 2 and 3, those are the ones with the lowest energy. However, we find the metallic of GST326 configuration to be dynamically unstable. In general, our values of the Seebeck coefficient and thermal conductivity for compounds with x = 1 and 2 agree very well with the available experimental data. The small differences that we observe with respect to experimental data are attributed to the disorder that is present experimentally and that we have not taken into account. We do not find a Dirac cone in the electronic band structure of GST225, contrarily to previous reports. We attribute this due to the theoretical strain induced by the choice of the pseudopotential.

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Section: (Gete) 1 (Sb 2 Te 3 ) (Gst124)supporting

confidence: 78%

Section: (Gete) 1 (Sb 2 Te 3 ) (Gst124)supporting

confidence: 77%

Section: (Gete) 2 (Sb 2 Te 3 ) (Gst225)mentioning

confidence: 78%

Section: (Gete) 1 (Sb 2 Te 3 ) (Gst124)mentioning

confidence: 84%

“…[50]. Phonon band structure has been reported for some of these structures in the works of Campi et al [31,51].…”

Section: (Gete) 2 (Sb 2 Te 3 ) (Gst225)mentioning

confidence: 95%

See 3 more Smart Citations

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)
Ibarra-Hernández
¹
,
Raty
²

2018
Phys. Rev. B

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Exceptional Performance Driven by Planar Honeycomb Structure in a New High Temperature Thermoelectric Material BaAgAs

Peng

Zhou

Wang

et al. 2021

Adv Funct Materials

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The discovery of new, high‐performing thermoelectrics is of vital importance to promoting thermal energy conversion efficiency. Herein, a new p‐type thermoelectric material BaAgAs with an exceptional figure of merit (zT) surpassing 1.1 at 970 K is present as a promising candidate for high‐temperature applications. Verified by comprehensive experimental and theoretical investigations, BaAgAs possesses two intrinsic features in favoring zT: i) low lattice thermal conductivity, ascribed to the heavy element Ba in a loose mono‐hexagonal layer, the large mass fluctuation in the Ag‐As honeycomb layer, and the alternately interlayer stacking between mono‐hexagonal and honeycomb layers; ii) good electrical properties contributed by multiple band transport, due to the small band offset between two valence band extremums and the strong anisotropic band effective mass. With enhanced phonon–phonon scattering via Sb/Bi substitution on the As sites, the lattice thermal conductivity is minimized, which results in significantly enhanced zT values. Additionally, an inspiring prediction via the first‐principles calculation suggests that n‐type BaAgAs can potentially outperform its p‐type counterpart due to its higher conducting band degeneracy. This study will stimulate intense interests in the exploration of compounds with planar honeycomb structures as new high‐performance thermoelectric materials.

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Engineering Interfacial Effects in Electron and Phonon Transport of Sb₂Te₃/MoS₂ Multilayer for Thermoelectric ZT Above 2.0

Ahmad

Agarwal

Gonzalez‐Munoz

et al. 2022

Adv Funct Materials

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Efficient thermoelectric (TE) conversion of waste heat to usable energy is a holy grail promising to address major societal issues related to energy crisis and global heat management. For these to be economical, synthesis of a solid‐state material with a high figure‐of‐merit (ZT) values is the key, with characterization methods quantifying TE and heat transport properties being indispensable for guiding the development of such materials. In the present study, a large enhancement of the TE power factor in Sb2Te3/MoS2 multilayer structures is reported. A new approach is used to simultaneously experimentally determine the values of in‐plane (kxy) and out‐of‐pane (kz) thermal conductivities for multilayer samples with characteristic layer thickness of few nanometres, essential for the quantification of the ZT, the key parameter for the TE material. Combining simultaneous enhancement in the value of in‐plane power factor (to (4.9 ± 0.4) × mWm−1 K−2) and reduction of the in‐plane value of the thermal conductivity (to 0.7 ± 0.1 Wm−1 K−1) for Sb2Te3/MoS2 multilayer sample led to high values of ZT of 2.08 ± 0.37 at room temperature. The present study, therefore, sets the foundation for a new methodology of exploiting the properties of 2D/3D interfaces for the development of novel fully viable thermoelectric materials.

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First-principles calculation of lattice thermal conductivity in crystalline phase change materials: GeTe, Sb2Te3 , and Ge2

Cited by 109 publications

References 57 publications

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)
Ibarra-Hernández
¹
,
Raty
²

2018
Phys. Rev. B

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)
Ibarra-Hernández
¹
,
Raty
²

2018
Phys. Rev. B

Exceptional Performance Driven by Planar Honeycomb Structure in a New High Temperature Thermoelectric Material BaAgAs

Engineering Interfacial Effects in Electron and Phonon Transport of Sb₂Te₃/MoS₂ Multilayer for Thermoelectric ZT Above 2.0

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First-principles calculation of lattice thermal conductivity in crystalline phase change materials: GeTe, Sb2Te3 , and Ge2

Cited by 109 publications

References 57 publications

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)Ibarra-Hernández1, Raty2 2018Phys. Rev. B

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)Ibarra-Hernández1, Raty2 2018Phys. Rev. B

Exceptional Performance Driven by Planar Honeycomb Structure in a New High Temperature Thermoelectric Material BaAgAs

Engineering Interfacial Effects in Electron and Phonon Transport of Sb2Te3/MoS2 Multilayer for Thermoelectric ZT Above 2.0

Contact Info

Product

Resources

About

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)
Ibarra-Hernández
¹
,
Raty
²

2018
Phys. Rev. B

Ab initio density functional theory study of the electronic, dynamic, and thermoelectric properties of the crystalline pseudobinary chalcogenide (GeTe)x/(Sb2Te3)
Ibarra-Hernández
¹
,
Raty
²

2018
Phys. Rev. B

Engineering Interfacial Effects in Electron and Phonon Transport of Sb₂Te₃/MoS₂ Multilayer for Thermoelectric ZT Above 2.0