Enhanced Thermoelectric and Mechanical Performance in n-Type Yb-Filled Skutterudites through Aluminum Alloying

Qin, Dandan; Cui, Bo; Zhu, Jianbo; Shi, Wenjing; Qin, Haixu; Guo, Fengyun; Cao, Jian; Cai, Wei; Sui, Jiehe

doi:10.1021/acsami.0c01798

Cited by 24 publications

(26 citation statements)

References 57 publications

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“…This is mainly due to the decrease in the total filling fraction with the increased Al content. At the same time, more precipitated (Al, Ga)Co nanoparticles transfer electrons to the skutterudite matrix as the content of Al increases . Thus, all the multiple-filled samples present similar n H values, which fall into the optimal carrier concentration range of Co y Fe 4‑ y Sb 12 -based filled skutterudites …”

Section: Results and Discussionmentioning

confidence: 83%

Multiple-Filling-Induced Full-Spectrum Phonon Scattering and Band Convergence Leading to High-Performance n-Type Skutterudites

Zhang

Ren

et al. 2021

ACS Appl. Mater. Interfaces

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Filling guest atoms into the nanovoids of skutterudite compounds provides effective scattering for low-frequency phonons to reduce the lattice thermal conductivity. However, it is still difficult to simultaneously realize the full-spectrum phonon scattering and band engineering in the n-type skutterudites with higher thermoelectric performance. Here, we reveal that the combination of five types of element atoms in the lattice nanovoids brings about dense dislocations, abundant precipitated nanoparticles, and electronic band convergence in the n-type skutterudites. The Seebeck coefficient shows an increase with little deterioration on the carrier mobility due to the enhanced density of states near the Fermi level, leading to a 11% enhancement in the power factor at 823 K. The lattice thermal conductivity is significantly reduced to approach the glass limit due to the full-spectrum phonon scattering. As a result, a peak ZT value of about 1.7 at 823 K and an average ZT value of about 1.2 from 323 to 823 K are obtained. High thermoelectric performance combined with the structural optimization enables the simulated maximum energy conversion efficiency of the skutterudite module to reach up to 15.0%. Our finding opens a new dimension for doping atoms to achieve simultaneous optimization of electrical and thermal properties in polynary thermoelectric materials.

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Section: Results and Discussionmentioning

confidence: 83%

Multiple-Filling-Induced Full-Spectrum Phonon Scattering and Band Convergence Leading to High-Performance n-Type Skutterudites

Zhang

Ren

et al. 2021

ACS Appl. Mater. Interfaces

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“…In addition, introducing nanoscale second-phase into CoSb 3 -based materials to form nanocomposites can not only significantly reduce the thermal conductivity, but also may significantly affect the mechanical properties [158,177,[197][198][199][200][201] of CoSb 3 -based materials. Rogl and Rogl [199] reviewed systematically that nanoparticles can obviously change the mechanical properties of skutterudite TE materials.…”

Section: Low Dimensionalmentioning

confidence: 99%

“…This is mainly due to the establishment of a resistance against crack growth, a pinning effect in the embedded skutterudite matrix and a stronger interface between skutterudite matrix and nanoscale second-phases. The mechanical properties of different kinds of CoSb 3 -based nanocomposites were obviously changed by introducing some nanoparticles like Yb 2 O 3 [158], TiN [181,200], CoAl [197], CoSi [179], and SiC [198]. Qin et al [177] prepared Yb 0.3 Co 4 Sb 12 with in situ formed CoSi nanoprecipitates by adding the extra Co and Si.…”

Section: Low Dimensionalmentioning

confidence: 99%

A review of CoSb3-based skutterudite thermoelectric materials

et al. 2020

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The binary skutterudite CoSb3 is a narrow bandgap semiconductor thermoelectric (TE) material with a relatively flat band structure and excellent electrical performance. However, thermal conductivity is very high because of the covalent bond between Co and Sb, resulting in a very low ZT value. Therefore, researchers have been trying to reduce its thermal conductivity by the different optimization methods. In addition, the synergistic optimization of the electrical and thermal transport parameters is also a key to improve the ZT value of CoSb3 material because the electrical and thermal transport parameters of TE materials are closely related to each other by the band structure and scattering mechanism. This review summarizes the main research progress in recent years to reduce the thermal conductivity of CoSb3-based materials at atomic-molecular scale and nano-mesoscopic scale. We also provide a simple summary of achievements made in recent studies on the non-equilibrium preparation technologies of CoSb3-based materials and synergistic optimization of the electrical and thermal transport parameters. In addition, the research progress of CoSb3-based TE devices in recent years is also briefly discussed.

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“…Complex crystal structures, dispersive bands, and nonclassical bonding interactions yield Zintl phases with intrinsic “phonon-glass, electron-crystal (PGEC)” nature, making great advantages for devising many well-known TE (thermoelectric) systems. − Layered structures often prove effective in the PGEC properties of compounds: not only do their two-dimensional (2D) anionic frameworks facilitate good electrical conductivity derived from high carrier mobility but also the cations serve as additional phonon scattering centers, contributing to the low thermal conductivity. , More importantly, because layered substructures spatially isolate the electron conduction path from the phonon scattering region, synergistic manipulation for electrical and thermal transport properties may be relatively easier to achieve in layered structures. The n-type Mg 3 Bi 2 -based compounds with the CaAl 2 Si 2 -type layered structure have attracted much attention because of their excellent TE properties at room temperature (RT) .…”

Section: Introductionmentioning

confidence: 99%

Phase Transitions, Structure Evolution, and Thermoelectric Properties Based on A₂MnSb₂ (A = Ca, Yb)

Liu

et al. 2021

Chem. Mater.

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Layered structures can facilitate "phonon-glass, electron-crystal (PGEC)" properties, which are crucial for the design of the state-of-the-art thermoelectric materials. In this report, two Mn-containing metastable Zintl phases with layered structures, Ca 2 MnSb 2 and Yb 2 MnSb 2 , are discovered for the first time. Their structures are isotypic to that of LiZnSb with transition-metal sites partially occupied. Interestingly, these compounds feature very broad homogeneity ranges, which enable flexible tuning on the Mn sites. In addition, close relationships to previously reported Yb 9 Mn 4+x Sb 9 series have been well established by phase exploration, and structure transition from Yb 2 MnSb 2 to Yb 9 Mn 4+x Sb 9 was experimentally observed after annealing. The thermal stability of A 2 MnSb 2 (A = Ca, Yb) can be significantly improved through Ag doping on the Mn sites, based on which, systematic investigations on the crystal structures and thermoelectric properties were carried out. Benefited from the complex anionic structures, the thermal conductivity of these phases is extremely low, that is, the Yb-containing material Yb 2 (Mn 0.9 Ag 0.2 )Sb 2 features glasslike thermal conductivity with a minimum value of 0.42 W•m −1 •K −1 at 673 K, and meanwhile, a high Seebeck coefficient of 208 μV•K −1 was obtained at 673 K. The discovery of such A 2 MnSb 2 (A = Ca, Yb) phases completed the critical missing members of the A−Mn−Sb ternary family, which is crucial for understanding the structure and properties related to these novel phases, and with the progress of such studies, the design of the state-of-the-art thermoelectric materials based on such Zintl phases is very promising.

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Enhanced Thermoelectric and Mechanical Performance in n-Type Yb-Filled Skutterudites through Aluminum Alloying

Cited by 24 publications

References 57 publications

Multiple-Filling-Induced Full-Spectrum Phonon Scattering and Band Convergence Leading to High-Performance n-Type Skutterudites

Multiple-Filling-Induced Full-Spectrum Phonon Scattering and Band Convergence Leading to High-Performance n-Type Skutterudites

A review of CoSb3-based skutterudite thermoelectric materials

Phase Transitions, Structure Evolution, and Thermoelectric Properties Based on A₂MnSb₂ (A = Ca, Yb)

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Enhanced Thermoelectric and Mechanical Performance in n-Type Yb-Filled Skutterudites through Aluminum Alloying

Cited by 24 publications

References 57 publications

Multiple-Filling-Induced Full-Spectrum Phonon Scattering and Band Convergence Leading to High-Performance n-Type Skutterudites

Multiple-Filling-Induced Full-Spectrum Phonon Scattering and Band Convergence Leading to High-Performance n-Type Skutterudites

A review of CoSb3-based skutterudite thermoelectric materials

Phase Transitions, Structure Evolution, and Thermoelectric Properties Based on A2MnSb2 (A = Ca, Yb)

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Phase Transitions, Structure Evolution, and Thermoelectric Properties Based on A₂MnSb₂ (A = Ca, Yb)