Thermoelectric Performance of IV–VI Compounds with Octahedral‐Like Coordination: A Chemical‐Bonding Perspective

Cagnoni, Matteo; Führen, Daniel; Wuttig, Matthias

doi:10.1002/adma.201801787

Cited by 90 publications

(104 citation statements)

References 63 publications

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“…A larger band anisotropy is beneficial for the thermoelectric performance, since it allows to maximize thermoelectric performance. A systematic study of the band anisotropy and power factor for (GeTe) 1− x –(GeSe) x solid solution may help answer this question . Figure a shows that with increasing the content of GeSe, the ternary alloy undergoes a phase transition from rhombohedral to hexagonal at x > 0.65, while the pure GeSe phase is orthorhombic.…”

Section: Band Engineering By Tuning the Chemical Bondmentioning

confidence: 99%

“…Then, the trend of the effective mass tensor with respect to changes in bond parameters can be inferred from the corresponding changes in the bandwidths along the principal axes. This description has been successfully implemented by means of s–p 3 next‐nearest‐neighbor tight‐binding model . It has been shown that increasing s–p mixing between cation s and anion p states increases the bandwidth along Γ–L with respect to the one along L–W, hence reducing the ratio between longitudinal and transverse effective masses .…”

Section: Band Engineering By Tuning the Chemical Bondmentioning

confidence: 99%

“…Then, materials whose trade‐off between stoichiometry and distortion effects leads to small effective s–p matrix element should have the most anisotropic carrier pockets. Those include materials with metavalent bonding, for example, GeTe, PbTe, Bi 2 Te 3 , and AgBiSe 2 , etc.…”

Section: Band Engineering By Tuning the Chemical Bondmentioning

confidence: 99%

“…A systematic study of the band anisotropy and power factor for (GeTe) 1−x -(GeSe) x solid solution may help answer this question. [110] Figure 9a shows that with increasing the content of GeSe, the ternary alloy undergoes a phase transition from rhombohedral to hexagonal at x > 0.65, while the pure GeSe phase is orthorhombic. The phase transition from rhombohedral to hexagonal is accompanied also by a change of chemical bonding from metavalent to covalent as confirmed by previous studies.…”

Section: Band Anisotropymentioning

confidence: 99%

“…This description has been successfully implemented by means of s-p 3 next-nearest-neighbor tight-binding model. [110] It has been shown that increasing s-p mixing between cation s and anion p states increases the bandwidth along Γ-L with respect to the one along L-W, hence reducing the ratio between longitudinal and transverse effective masses. [69] A similar effect is caused by larger ionicity, which leads to a shorter lattice constant and increased bond strength between adjacent p-orbitals in a σ-bonding configuration.…”

Section: Band Anisotropymentioning

confidence: 99%

See 4 more Smart Citations

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Cagnoni

Cojocaru‐Mirédin

et al. 2019

Adv Funct Materials

Self Cite

179

214

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Thermoelectric materials have attracted significant research interest in recent decades due to their promising application potential in interconverting heat and electricity. Unfortunately, the strong coupling between the material parameters that determine thermoelectric efficiency, i.e., the Seebeck coefficient, electrical conductivity, and thermal conductivity, complicates the optimization of thermoelectric energy converters. Main‐group chalcogenides provide a rich playground to alleviate the interdependence of these parameters. Interestingly, only a subgroup of octahedrally coordinated chalcogenides possesses good thermoelectric properties. This subgroup is also characterized by other outstanding characteristics suggestive of an exceptional bonding mechanism, which has been coined metavalent bonding. This conclusion is further supported by a map that separates different bonding mechanisms. In this map, all octahedrally coordinated chalcogenides with good performance as thermoelectrics are located in a well‐defined region, implying that the map can be utilized to identify novel thermoelectrics. To unravel the correlation between chemical bonding mechanism and good thermoelectric properties, the consequences of this unusual bonding mechanism on the band structure are analyzed. It is shown that features such as band degeneracy and band anisotropy are typical for this bonding mechanism, as is the low lattice thermal conductivity. This fundamental understanding, in turn, guides the rational materials design for improved thermoelectric performance by tailoring the chemical bonding mechanism.

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Section: Band Engineering By Tuning the Chemical Bondmentioning

confidence: 99%

Section: Band Engineering By Tuning the Chemical Bondmentioning

confidence: 99%

Section: Band Engineering By Tuning the Chemical Bondmentioning

confidence: 99%

Section: Band Anisotropymentioning

confidence: 99%

Section: Band Anisotropymentioning

confidence: 99%

See 3 more Smart Citations

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Cagnoni

Cojocaru‐Mirédin

et al. 2019

Adv Funct Materials

Self Cite

179

214

View full text Add to dashboard Cite

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Thermoelectrics: From Thermoelectric Figure of Merit to Device Design

Xu¹,

Liang²,

Song³

et al. 2022

Digital Encyclopedia of Applied Physics

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Thermoelectrics is defined as direct energy conversion between the heat and electricity associated with thermoelectric power generation and refrigeration. Significant progress has been made in the theoretical understanding, materials and device preparation technology, and performance improvement of thermoelectrics since the Seebeck effect was found 200 years ago. Herein, the article starts with the basic physics concepts underlying the thermoelectric phenomenon, and the key descriptor for evaluating thermoelectric performance, the thermoelectric figure of merit ( ZT ), is introduced. The corresponding issues and strategies for pursuing higher ZT are discussed in detail, and a brief introduction of organic thermoelectric materials is given. The leading engineering challenges from the material to the device are further elaborated based on the state‐of‐the‐art device design. This article aims to provide the reader with a comprehensive overview of the scope of activities related to this area of scientific endeavor.

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Impact of Bonding on the Stacking Defects in Layered Chalcogenides

Mio

Konze

Meledin

et al. 2019

Adv Funct Materials

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Phase‐change materials for high‐density data storage traditionally exploit the amorphous‐to‐crystalline phase transition. A number of these compounds are organized in blocks, separated by van der Waals‐like gaps. Such layered chalcogenides are attracting interest due to their unique material properties and the possibility to change their properties upon local rearrangements at the gap, giving rise to novel applications. To better understand the behavior of layered chalcogenides, the connection between structural defects, physical properties, and the bonding situation is highlighted here using electron microscopy, X‐ray diffraction, and density functional theory. In particular, stacking defects in hexagonal Ge4Se3Te, GaSe, and Sb2Te3 are characterized experimentally, followed by an investigation of the influence of observed and hypothetical stacking defects on optical and electronic properties by theoretical means. Then, a connection between observed defects and the bonding situation in these materials is drawn and related to the presence of van der Waals and metavalent bonding in chalcogenides. Finally, additional experiments are performed to validate the conclusions for other metavalently bonded layered chalcogenides. Transmission electron microscopy provides a powerful tool for direct detection of defects and, when combined with diffraction experiments and ab initio theory, it facilitates the precise investigation of the bonding mechanisms in layered chalcogenides.

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Thermoelectric Performance of IV–VI Compounds with Octahedral‐Like Coordination: A Chemical‐Bonding Perspective

Cited by 90 publications

References 63 publications

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Thermoelectrics: From Thermoelectric Figure of Merit to Device Design

Impact of Bonding on the Stacking Defects in Layered Chalcogenides

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