Gigantic Phonon-Scattering Cross Section To Enhance Thermoelectric Performance in Bulk Crystals

Hwang, Junphil; Kim, Hoon; Han, Mi Kyung; Hong, Jisook; Shim, Ji Hoon; Tak, Jang Yeul; Lim, Young Soo; Yu, Jingui; Kim, Jiyong; Park, Hwanjoo; Lee, Dong Hoon; Bahk, Je‐Hyeong; Kim, Sung Jin; Kim, Woochul

doi:10.1021/acsnano.9b03805

Cited by 61 publications

(65 citation statements)

References 52 publications

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“…The introduction of Te nanoneedles into the SnSe resulted in the formation of heterointerfaces between the Te and SnSe, which acted as effective phonon scattering centers. Thus, the κ values of the Te nanoneedles(x)/SnSe composites were lower than that of pristine SnSe, in accordance with the previous reports on the phonon scattering in composite materials [30][31][32]. The κ value of the pristine SnSe was restricted efficiently by the scattering of phonons at the heterointerfaces for reaction times of up to 4 h. With reaction times greater than 4 h, the κ value subsequently increased as the higher volumetric fraction of Te nanoneedles in the composite (Table S1) [26][27][28][29].…”

Section: Resultssupporting

confidence: 91%

Te Nanoneedles Induced Entanglement and Thermoelectric Improvement of SnSe

Kim

Yang

et al. 2020

Materials

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Chalcogenide-based materials have attracted widespread interest in high-performance thermoelectric research fields. A strategy for the application of two types of chalcogenide for improved thermoelectric performance is described herein. Tin selenide (SnSe) is used as a base material, and Te nanoneedles are crystallized in the SnSe, resulting in the generation of a composite structure of SnSe with Te nanoneedles. The thermoelectric properties with various reaction times are investigated to reveal the optimum conditions for enhanced thermoelectric performance. A reaction time of 4 h at 450 K generated a composite Te nanoneedles/SnSe sample with the maximum ZT value, 3.2 times larger than that of the pristine SnSe. This result is attributed to both the reduced thermal conductivity from the effective phonon scattering of heterointerfaces and the improved electrical conductivity value due to the introduction of Te nanoparticles. This strategy suggests an approach to generating high-performance practical thermoelectric materials.

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Section: Resultssupporting

confidence: 91%

Te Nanoneedles Induced Entanglement and Thermoelectric Improvement of SnSe

Kim

Yang

et al. 2020

Materials

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“…Very recently, a novel approach has been introduced to realize a huge phonon scattering process by incorporating CdTe‐coated layers on the surface of SnTe grains. [ 36 ] The authors explained that such scattering is induced by the acoustic impedance mismatch between the CdTe‐coated layer and the SnTe grain. Interestingly, in all these examples the matrix is an MVB material, whereas the nanostructure is a non‐MVB material, more specifically a covalently bonded material.…”

Section: Resultsmentioning

confidence: 99%

Employing Interfaces with Metavalently Bonded Materials for Phonon Scattering and Control of the Thermal Conductivity in TAGS‐x Thermoelectric Materials

Rodenkirchen

Cagnoni

Jakobs

et al. 2020

Adv Funct Materials

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The thermoelectric compound (GeTe) x (AgSbTe 2 ) 1−x , in short (TAGS-x), is investigated with a focus on two stoichiometries, i.e., TAGS-50 and TAGS-85. TAGS-85 is currently one of the most studied thermoelectric materials with great potential for thermoelectric applications. Yet, surprisingly, the lowest thermal conductivity is measured for TAGS-50, instead of TAGS-85. To explain this unexpected observation, atom probe tomography (APT) measurements are conducted on both samples, revealing clusters of various compositions and sizes. The most important role is attributed to Ag 2 Te nanoprecipitates (NPs) found in TAGS-50. In contrast to the Ag 2 Te NPs, the matrix reveals an unconventional bond breaking mechanism. More specifically, a high probability of multiple events (PME) of ≈60% is observed for the matrix by APT. Surprisingly, the PME value decreases abruptly to ≈20-30% for the Ag 2 Te NPs. These differences can be attributed to differences in chemical bonding. The precipitates' PME value is indicative of normal bonding, i.e., covalent bonding with normal optical modes, while materials with this unconventional bond breaking found in the matrix are characterized by metavalent bonding. This implies that the interface between the metavalently bonded matrix and covalently bonded Ag 2 Te NP is partly responsible for the reduced thermal conductivity in TAGS-50.

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“…[ 2 ] The above three parameters are intrinsically coupled; therefore, it is difficult to enhance these parameters simultaneously. Some effective strategies have been reported for enhancing TE properties, such as modulation doping, [ 3 ] band engineering, [ 4 ] nanostructuring, [ 5 ] grain boundary engineering, [ 3a,6 ] energy filtering, [ 7 ] compositing, [ 8 ] microstructure control. [ 9 ]…”

Section: Introductionmentioning

confidence: 99%

Realizing High Thermoelectric Performance in Earth‐Abundant Bi₂S₃ Bulk Materials via Halogen Acid Modulation

Guo

Yang

et al. 2021

Adv Funct Materials

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Bi2S3‐based thermoelectric materials without toxic and expensive elements have a high Seebeck coefficient and intrinsic low thermal conductivity. However, Bi2S3 suffers from low electrical conductivity, which makes it a less‐than‐perfect thermoelectric material. In this work, halogen elements F, Cl, and Br from halogen acid are successfully introduced into the Bi2S3 lattice using a hydrothermal procedure to efficiently improve the carrier concentration. Compared with the pure sample, the electron concentration of the Bi2S3 sample treated with HCl is increased by two orders of magnitude. An optimal power factor of 470 µW m−1 K−2 for the Bi2S2.96Cl0.04 sample at 673 K is obtained. Density functional theory calculations reveal that an effective delocalized electron conductive network forms after Cl doping, which raises the Fermi level into the conduction bands, thus generating more free electrons and improving the conductivity of the Bi2S3‐based materials. Ultimately, an excellent ZT of ≈0.8 is achieved at 673 K for the Bi2S2.96Cl0.04 sample, which is one of the highest values reported for a state‐of‐the‐art Bi2S3 system. The energy conversion efficiency of the module reaches 2.3% at 673 K with a temperature difference of 373 K. This study offers a new method for enhancing the thermoelectric properties of Bi2S3 by adding halogen acid in the hydrothermal process for powder synthesis.

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Gigantic Phonon-Scattering Cross Section To Enhance Thermoelectric Performance in Bulk Crystals

Cited by 61 publications

References 52 publications

Te Nanoneedles Induced Entanglement and Thermoelectric Improvement of SnSe

Te Nanoneedles Induced Entanglement and Thermoelectric Improvement of SnSe

Employing Interfaces with Metavalently Bonded Materials for Phonon Scattering and Control of the Thermal Conductivity in TAGS‐x Thermoelectric Materials

Realizing High Thermoelectric Performance in Earth‐Abundant Bi₂S₃ Bulk Materials via Halogen Acid Modulation

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Gigantic Phonon-Scattering Cross Section To Enhance Thermoelectric Performance in Bulk Crystals

Cited by 61 publications

References 52 publications

Te Nanoneedles Induced Entanglement and Thermoelectric Improvement of SnSe

Te Nanoneedles Induced Entanglement and Thermoelectric Improvement of SnSe

Employing Interfaces with Metavalently Bonded Materials for Phonon Scattering and Control of the Thermal Conductivity in TAGS‐x Thermoelectric Materials

Realizing High Thermoelectric Performance in Earth‐Abundant Bi2S3 Bulk Materials via Halogen Acid Modulation

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Realizing High Thermoelectric Performance in Earth‐Abundant Bi₂S₃ Bulk Materials via Halogen Acid Modulation