Charge and phonon transport in PbTe-based thermoelectric materials

Xiao, Yu; Zhao, Li‐Dong

doi:10.1038/s41535-018-0127-y

Cited by 257 publications

(140 citation statements)

References 128 publications

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“…Single phase TE materials are widely studied, among them are PbTe, PbSe,7b Bi 2 Te 3 , skutterudites, clathrates, and half‐Heusler (HH)6a alloys typically exhibit zT values around 1 through simple doping, whereas further improvement in zT could be attained by adopting the aforementioned strategies. The scientific community has faced a few challenging problems, such as reproducibility of stoichiometry,4a control over properties for a wide temperature range and, most importantly, tuning both S and σ simultaneously 7b.…”

Section: Introductionmentioning

confidence: 99%

Energy Filtering of Charge Carriers: Current Trends, Challenges, and Prospects for Thermoelectric Materials

Gayner

Amouyal

2019

Adv Funct Materials

325

231

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Exhaustive attempts are made in recent decades to improve the performance of thermoelectric materials that are utilized for waste heat-to-electricity conversion. Energy filtering of charge carriers is directed toward enhancing the material thermopower. This paper focuses on the theoretical concepts, experimental evidence, and the authors' view of energy filtering in the context of thermoelectric materials. Recent studies suggest that not all materials experience this effect with the same intensity. Although this effect theoretically demonstrates improvement of the thermopower, applying it poses certain constraints, which demands further research. Predicated on data documented in literature, the unusual dependence of the thermopower and conductivity upon charge carrier concentrations can be altered through the energy filtering approach. Upon surmounting the physical constraints discussed in this article, thermoelectric materials research may gain a new direction to enhance the power factor and thermoelectric figure of merit.

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Section: Introductionmentioning

confidence: 99%

Energy Filtering of Charge Carriers: Current Trends, Challenges, and Prospects for Thermoelectric Materials

Gayner

Amouyal

2019

Adv Funct Materials

325

231

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“…First, most of them can easily be doped into p‐type or n‐type, which is critical for the assembly of thermoelectric devices . Second, they consist of heavy elements and soft chemical bonds, resulting in low thermal conductivity . Third, they possess a variety of structures, providing a good platform for manipulating the thermoelectric performance.…”

Section: Introductionmentioning

confidence: 99%

“…Some rare‐earth chalcogenides can even be used above 1000 K due to their high thermal stability, such as La 3− x Te 4 which exhibits a maximum zT of ≈1.1 at 1275 K . More comprehensive discussions of the thermoelectric properties of chalcogenide compounds can be found elsewhere …”

Section: Introductionmentioning

confidence: 99%

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Cagnoni

Cojocaru‐Mirédin

et al. 2019

Adv Funct Materials

180

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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“…[ 26–30 ] High‐performance thermoelectric materials require high S , high σ, and low κ. [ 24,31–34 ] However, due to the strong coupling between these parameters, the optimization of thermal/electrical transport properties is the key for ZT enhancement. [ 35–40 ] The performance of thermoelectric materials can be enhanced from the two aspects: 1) optimization of electrical transportation performance and 2) minimization of thermal transport properties.…”

Section: Introductionmentioning

confidence: 99%

“…n p can be optimized by aliovalent substitutions [ 85 ] and Ge vacancy engineering. [ 85,86 ] Tuning the band structure can be realized by bandgap engineering, [ 32 ] band degeneracy engineering, [ 87 ] and resonant state engineering. [ 88 ] Reducing κ l can be achieved by strengthening the phonon–phonon scattering (reducing v ) [ 73 ] and introducing multiple phonon scattering centers (reducing relaxation time, τ).…”

Section: Introductionmentioning

confidence: 99%

High‐Performance GeTe‐Based Thermoelectrics: from Materials to Devices

Liu

Wang

et al. 2020

Advanced Energy Materials

183

128

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m ), [52] enlarging band degeneracy (N V ), [43] and introducing resonant energy levels, [26] can also tune n p effectively. Taking Ge 1−x−y Sb x Zn y Te as an example, Zn doping can reduce the energy offset (ΔE) between L and Σ point. [52] The minimization of thermal transport properties is mainly achieved through suppressing the electrical property-independent κ l . [53][54][55][56][57] Thermoelectric materials with High-performance GeTe-based thermoelectrics have been recently attracting growing research interest. Here, an overview is presented of the structural and electronic band characteristics of GeTe. Intrinsically, compared to lowtemperature rhombohedral GeTe, the high-symmetry and high-temperature cubic GeTe has a low energy offset between L and Σ points of the valence band, the reduced direct bandgap and phonon group velocity, and as a result, high thermoelectric performance. Moreover, their thermoelectric performance can be effectively enhanced through either carrier concentration optimization, band structure engineering (bandgap reduction, band degeneracy, and resonant state engineering), or restrained lattice thermal conductivity (phonon velocity reduction or phonon scattering). Consequently, the dimensionless figure of merit, ZT values, of GeTe-based thermoelectric materials can be higher than 2. The mechanical and thermal stabilities of GeTe-based thermoelectrics are highlighted, and it is found that they are suitable for practical thermoelectric applications except for their high cost. Finally, it is recognized that the performance of GeTe-based materials can be further enhanced through synergistic effects. Additionally, proper material selection and module design can further boost the energy conversion efficiency of GeTe-based thermoelectrics.

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Charge and phonon transport in PbTe-based thermoelectric materials

Cited by 257 publications

References 128 publications

Energy Filtering of Charge Carriers: Current Trends, Challenges, and Prospects for Thermoelectric Materials

Energy Filtering of Charge Carriers: Current Trends, Challenges, and Prospects for Thermoelectric Materials

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

High‐Performance GeTe‐Based Thermoelectrics: from Materials to Devices

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