Superflexible Inorganic Ag2Te0.6S0.4 Fiber with High Thermoelectric Performance

Fu, Yanqing; Kang, Shiliang; Gu, Hao; Tan, Linling; Gao, Chengwei; Fang, Zaijin; Dai, Shixun; Lin, Changgui

doi:10.1002/advs.202207642

Cited by 24 publications

(12 citation statements)

References 55 publications

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“…In Figure g, by comparing and analyzing the results of this study with those of other similar works and photothermal electrical components, we find that the work of this study is competitive. There is still a lot of unexplored potential in the field of photothermal electrical devices, and this work contributes positively to the development of this field and provides certain reference values for future research. ,,,,,− …”

Section: Results and Discussionmentioning

confidence: 80%

Photothermoelectric Synergistic Hydrovoltaic Effect: A Flexible Photothermoelectric Yarn Panel for Multiple Renewable-Energy Harvesting

Li,

Fan,

Zhang

et al. 2023

ACS Appl. Mater. Interfaces

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Section: Results and Discussionmentioning

confidence: 80%

Photothermoelectric Synergistic Hydrovoltaic Effect: A Flexible Photothermoelectric Yarn Panel for Multiple Renewable-Energy Harvesting

Li,

Fan,

Zhang

et al. 2023

ACS Appl. Mater. Interfaces

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“…In flexible all-inorganic devices based on such Ag 2 S-based materials, the high electrical mobility results in a normalized maximum ω out of up to 0.08 W m −1 at a ΔT close to 20 K. Therefore, rational adjustment of the ratios of S, Se, and Te can achieve materials with both reasonable flexibility and thermoelectric performance to meet specific devices. 43,45,137,[142][143][144][145][146][147][148][149] Besides, some materials with unique composition, such as Ag 20 S 7 Te 3 , also exhibit ductile and promising ZT of 0.8 at 600 K. 150 Based on the compositional design of Ag 2 S 1−x−y Se x-Te y , in addition to conventional doping to further improve their thermoelectric performance, 151 substituting Cu on Ag sites can further tune the thermoelectric performance and flexibility. 107,152 This is because Cubased chalcogenides such as Cu 2 S 153 and Cu 2 Se 22 have demonstrated their high ZTs of >2 at high temperatures, and they are usually p-type semiconductors.…”

Section: Chalcogenides and Their Hybridsmentioning

confidence: 99%

“…Given the rapid development in the field of flexible inorganic thermoelectrics, this article comprehensively overviews the advances with a focus on the optimization of their structures and performance. Here, we encompass an overview and synthesis of the preparation methods and practical application areas of inorganic flexible thermoelectric materials and their devices, including Bi 2 Te 3−x Se x , 41 Bi 2−x Sb x Te 3 , 42 Ag 2 X (X = S, Se, Te), [43][44][45] SnX (X = S, Se, Te), 46 InSe, 47 Cu 2 Se, 48 TiS 2 , 49 CoSb 3 , 50 oxides, 51,52 and complex chalcogenides, 53 as illustrated in Figure 1. Furthermore, this review also addresses the challenges currently faced in terms of performance optimization and fabrication processes of flexible inorganic thermoelectric materials.…”

mentioning

confidence: 99%

Advances in flexible inorganic thermoelectrics

Shi,

Cao,

Chen

et al. 2023

EcoEnergy

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Solid‐state bismuth telluride‐based thermoelectric devices enable the generation of electricity from temperature differences and have been commercially applied in various fields. However, in many scenarios, the surface of the heat source is not flat. Therefore, it is crucial to develop flexible thermoelectric materials and devices to efficiently utilize heat sources and expand their applications. Compared with organic thermoelectric materials and devices, inorganic flexible thermoelectric materials and devices have much higher thermoelectric performance and stability. Considering the rapid development in this research field, we carefully summarize the design principles, structures, and thermoelectric properties of inorganic flexible materials and their devices reported in the recent 3 years, including sulfides, selenides, tellurides, and composite materials designed based on these inorganics. The structural designs of flexible thermoelectric devices based on micro‐sized bulk materials are also carefully summarized. Additionally, we overview the mechanical stability and methods for reducing internal resistance for designs of inorganic flexible thermoelectric devices. In the end, we provide outlooks on future research directions for inorganic flexible thermoelectric materials and devices. This review will help guide thermoelectric researchers, beginners, and students.

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“…Subsequently, the flexibility of single-crystal ZnS in the complete darkness and single-crystal InSe is revealed. The relatively large bandgap (∼1 eV) of Ag 2 S gives electrical conductivity on the order of 10 –1 S m –1 , resulting in poor TE performance. , Alloying a certain amount of Se − or Cu , to Ag 2 S is an effective way to improve its TE performance at ambient temperature, and the discovery of amorphous Ag 2 S 0.4 Te 0.6 provides another new idea for optimizing the deformability and TE performance of ductile inorganic semiconductor. − …”

Section: Introductionmentioning

confidence: 99%

Flexible Ag–S–Te System with Promising Room-Temperature Thermoelectric Performance

Zhang

Luo

et al. 2023

ACS Appl. Mater. Interfaces

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Silver chalcogenides demonstrate great potential as flexible thermoelectric materials due to their excellent ductility and tunable electrical and thermal transport properties. In this work, we report that the amorphous/crystalline phase ratio and thermoelectric properties of the Ag2S x Te1–x (x = 0.55–0.75) samples can be modified by altering the S content. The room-temperature power factor of the Ag2S0.55Te0.45 sample is 4.9 μW cm–1 K–2, and a higher power factor can be achieved by decreasing the carrier concentration as predicted by the single parabolic band model. The addition of a small amount of excessive Te into Ag2S0.55Te0.45 (Ag2S0.55Te0.45+y ) not only enhances the power factor by decreasing the carrier concentration but also reduces the total thermal conductivity due to decreased electronic thermal conductivity. Owing to the effectively optimized carrier concentration, the thermoelectric power factor and dimensionless figure of merit zT of the sample with y = 0.007 reaches, respectively, 6.2 μW cm–1 K–2 and 0.39, while the excellent plastic deformability is well maintained, demonstrating its promising potential as a flexible thermoelectric material at room temperature.

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Superflexible Inorganic Ag₂Te_0.6S_0.4 Fiber with High Thermoelectric Performance

Cited by 24 publications

References 55 publications

Photothermoelectric Synergistic Hydrovoltaic Effect: A Flexible Photothermoelectric Yarn Panel for Multiple Renewable-Energy Harvesting

Photothermoelectric Synergistic Hydrovoltaic Effect: A Flexible Photothermoelectric Yarn Panel for Multiple Renewable-Energy Harvesting

Advances in flexible inorganic thermoelectrics

Flexible Ag–S–Te System with Promising Room-Temperature Thermoelectric Performance

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