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

Liu, Wei‐Di; Wang, De‐Zhuang; Li, Qingfeng; Zhou, Wei; Shao, Zongping; Chen, Huajun

doi:10.1002/aenm.202000367

Cited by 182 publications

(141 citation statements)

References 168 publications

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“…[57] Within the low-temperature range (<500 K), the zT values of these materials are generally lower than unity. [14,27,58] Among them, Bi 2 Te 3 - [31,[59][60][61] and Bi 0.5 Sb 1.5 Te 3based [62][63][64] materials show room-temperature zT values of >1 (Figure 6a) and have an applicable energy conversion efficiency for wearable electrocardiographic systems. [16,27,65,66] However, the rigidity of these materials is a major obstacle because it significantly effects the comfort of the person wearing the system and the coupling of the device to the body heat source.…”

Section: Wearable Thermoelectric Materialsmentioning

confidence: 99%

Thermoelectric Generators: Alternative Power Supply for Wearable Electrocardiographic Systems

2020

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Research interest in the development of real‐time monitoring of personal health indicators using wearable electrocardiographic systems has intensified in recent years. New advanced thermoelectrics are potentially a key enabling technology that can be used to transform human body heat into power for use in wearable electrographic monitoring devices. This work provides a systematic review of the potential application of thermoelectric generators for use as power sources in wearable electrocardiographic monitoring systems. New strategies on miniaturized rigid thermoelectric modules combined with batteries or supercapacitors can provide adequate power supply for wearable electrocardiographic systems. Flexible thermoelectric generators can also support wearable electrocardiographic systems directly when a heat sink is incorporated into the design in order to enlarge and stabilize the temperature gradient. Recent advances in enhancing the performance of novel fiber/fabric based flexible thermoelectrics has opened up an exciting direction for the development of wearable electrocardiographic systems.

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Section: Wearable Thermoelectric Materialsmentioning

confidence: 99%

Thermoelectric Generators: Alternative Power Supply for Wearable Electrocardiographic Systems

2020

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“…Thermoelectric materials have the ability to directly and reversibly convert a thermal gradient into electrical energy, offering an elegant and versatile way to recover energy from any heat source. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15] Thermoelectric generators (TEGs), consisting of n-and p-type legs composed of doped semiconductors, have been mostly used as reliable power supplies for rovers and deepspace probes. [10,11] Despite being an attractive solid-state technology primarily due to its high reliability and absence of greenhouse gas emissions, the limited use of TEGs in terrestrial applications is tied to their output performances, still surpassed by other green energyconversion technologies such as solar cells.…”

Section: Introductionmentioning

confidence: 99%

High Power Density Thermoelectric Generators with Skutterudites

Oualid

Kogut

Benyahia

et al. 2021

Advanced Energy Materials

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Thermoelectric generators (TEGs) offer a versatile solution to convert low‐grade heat into useful electrical power. While reducing the length of the active thermoelectric legs provides an efficient strategy to increase the maximum output power density pmax, both the high electrical contact resistances and thermomechanical stresses are two central issues that have so far prevented a strong reduction in the volume of thermoelectric materials integrated. Here, it is demonstrated that these barriers can be lifted by using a nonconventional architecture of the legs which involves inserting thick metallic layers. Using skutterudites as a proof‐of‐principle, several single‐couple and multi‐couple TEGs with skutterudite layers of only 1 mm are fabricated, yielding record pmax ranging from 3.4 up to 7.6 W cm−2 under temperature differences varying between 450 and 630 K. The highest pmax achieved corresponds to a 60‐fold increase per unit volume of skutterudites compared to 1 cm long legs. This work establishes thick metallic layers as a robust strategy through which high power density TEGs may be developed.

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“…Specifically, σ and S can hardly increase simultaneously as these two parameters are coupled via carrier concentration [ 13 , 14 ]. Besides, the reduction of κ often degrades the carrier mobility and thus σ [ 15 – 17 ]. Conflicts between these properties impede the limitless enhancement of zT , where a compromise is necessary to optimize zT .…”

Section: Introductionmentioning

confidence: 99%

Multiscale architectures boosting thermoelectric performance of copper sulfide compound

et al. 2021

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Owing to their high performance and earth abundance, copper sulfides (Cu 2− x S) have attracted wide attention as a promising medium-temperature thermoelectric material. Nanostructure and grain-boundary engineering are explored to tune the electrical transport and phonon scattering of Cu 2− x S based on the liquid-like copper ion. Here multiscale architecture-engineered Cu 2− x S are fabricated by a room-temperature wet chemical synthesis combining mechanical mixing and spark plasma sintering. The observed electrical conductivity in the multiscale architecture-engineered Cu 2− x S is four times as much as that of the Cu 2− x S sample at 800 K, which is attributed to the potential energy filtering effect at the new grain boundaries. Moreover, the multiscale architecture in the sintered Cu 2− x S increases phonon scattering and results in a reduced lattice thermal conductivity of 0.2 W·m −1 ·K −1 and figure of merit ( zT ) of 1.0 at 800 K. Such a zT value is one of the record values in copper sulfide produced by chemical synthesis. These results suggest that the introduction of nanostructure and formation of new interface are effective strategies for the enhancement of thermoelectric material properties. Supplementary Information The online version of this article (10.1007/s12598-020-01698-6) contains supplementary material, which is available to authorized users.

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

Cited by 182 publications

References 168 publications

Thermoelectric Generators: Alternative Power Supply for Wearable Electrocardiographic Systems

Thermoelectric Generators: Alternative Power Supply for Wearable Electrocardiographic Systems

High Power Density Thermoelectric Generators with Skutterudites

Multiscale architectures boosting thermoelectric performance of copper sulfide compound

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