Al–Si Alloy as a Diffusion Barrier for GeTe-Based Thermoelectric Legs with High Interfacial Reliability and Mechanical Strength

Li, Junqin; Zhao, Shiyuan; Chen, Jiali; Han, Cuiping; Hu, Lipeng; Liu, Fusheng; Ao, W.Q.; Liu, Yu; Xie, Heping; Zhang, Chaohua

doi:10.1021/acsami.0c02028

Cited by 25 publications

(27 citation statements)

References 46 publications

(107 reference statements)

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“…[ 16,25 ] This problem can be alleviated by introducing appropriate diffusion barriers between electrodes and TE legs. [ 25–29 ]…”

Section: Introductionmentioning

confidence: 99%

Boron Strengthened GeTe‐Based Alloys for Robust Thermoelectric Devices with High Output Power Density

Bai

et al. 2021

Advanced Energy Materials

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High‐performance thermoelectric (TE) devices require not only a high figure of merit (ZT) but also mechanical strength and thermal stability. Here, a simultaneous enhancement of ZT as well as mechanical properties is obtained in GeTe‐based alloys by adding boron. This material is then assembled with n‐type CoSb3 skutterudite into TE modules. The improved ZT values result from the increase in charge carrier mobility due to the reduced interfacial barrier height. A peak ZT of 2.2 at 773 K can be achieved in Ge0.84Pb0.1Sb0.06TeB0.07, which shows a negligible change in the coefficient of thermal expansion upon the phase transition from the rhombohedral to the cubic phase, ensuring good thermal stability of the device. Resulting from the boron‐induced grain refinement and dispersion strengthening, the average compressive strength and Vickers hardness of Ge0.9Sb0.1TeB0.07 can be enhanced to ≈227 MPa and ≈202 Hv, respectively. The improved mechanical properties facilitate the assembly of devices and lower the interfacial contact resistance. As a synergy of increased ZT and mechanical strength, a high output power density of ≈1.76 W cm−2 at ΔT = 425 K and an energy conversion efficiency of 7.4% at ΔT = 477 K can be achieved in the TE modules.

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“…[ 16,25 ] This problem can be alleviated by introducing appropriate diffusion barriers between electrodes and TE legs. [ 25–29 ]…”

Section: Introductionmentioning

confidence: 99%

Boron Strengthened GeTe‐Based Alloys for Robust Thermoelectric Devices with High Output Power Density

Bai

et al. 2021

Advanced Energy Materials

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“…This corresponds to an interfacial contact resistivity (ρ c ) of only ~8 microhm·cm 2 , which is one of the lowest among reported thermoelectric devices (fig. S11) ( 26 , 29 , 31 ). Note that the total resistance of contacts at both cold and hot sides is limited to be within 4% of the internal resistance ( R in ) of the device, ensuring the high power output and conversion efficiency ( 27 ).…”

Section: Resultsmentioning

confidence: 99%

“…One further step that has to be taken for realizing an efficient thermoelectric application of GeTe is the fabrication of high-efficiency devices. Both electrically and thermally conductive but chemically inert contacts between thermoelectric materials and electrodes are essential to ensure the high device efficiency offered by the high-performance materials ( 26 , 27 ). Usually, a stack of multiple layers can be applied for a prevention of atomic diffusion, a release of thermal expansion mismatch, and a reduction of contact resistance ( 28 , 29 ).…”

Section: Introductionmentioning

confidence: 99%

“…For GeTe-based devices, Fe and Ni were considered as electrodes, yet a direct bond to GeTe results in a notable atomic diffusion thus a notable decrease in conduction and efficiency ( 29 , 30 ). Existing work indicates that alloys ( 26 ), compounds ( 29 ), and metals ( 31 ) can be used as a medium between thermoelectric materials and electrodes for inhibiting atomic diffusion.…”

Section: Introductionmentioning

confidence: 99%

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Realizing a 14% single-leg thermoelectric efficiency in GeTe alloys

et al. 2021

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GeTe alloys have recently attracted wide attention as efficient thermoelectrics. In this work, a single-leg thermoelectric device with a conversion efficiency as high as 14% under a temperature gradient of 440 K was fabricated on the basis of GeTe-Cu2Te-PbSe alloys, which show a peak thermoelectric figure of merit (zT) > 2.5 and an average zT of 1.8 within working temperatures. The high performance of the material is electronically attributed to the carrier concentration optimization and thermally due to the strengthened phonon scattering, the effects of which all originate from the defects in the alloys. A design of Ag/SnTe/GeTe contact successfully enables both a prevention of chemical diffusion and an interfacial contact resistivity of 8 microhm·cm2 for the realization of highly efficient devices with a good service stability/durability. Not only the material’s high performance but also the device’s high efficiency demonstrated the extraordinariness of GeTe alloys for efficient thermoelectric waste-heat recovery.

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“…For instance, while it is generally desirable to have a high power factor (S 2 σ) and low thermal conductivity (κ L +κ e ), improving the electrical conductivity (σ) leads to higher electronic thermal conductivity (κ e ). In addition to optimizing thermoelectric properties, the mechanical properties such as hardness, stiffness, and thermal expansion coefficient cannot be overlooked to ensure practical applications [7–13] . With respect to its application temperature, thermoelectrics can be classified into low (300–500 K), medium (500–800 K), and high temperature (>800 K) materials.…”

Section: Introductionmentioning

confidence: 99%

Realizing zT Values of 2.0 in Cubic GeTe

et al. 2021

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Over the past two years, GeTe has quickly cemented its place as the best performing thermoelectric material at a medium temperature range. The key factors behind the extraordinary performance lie in its favourable electronic and thermal properties, which arise from its unique crystal structure. The slight rhombohedral distortion at temperatures below 700 K results in lower lattice thermal conductivity while maintaining high electronic properties via high level of band‐convergence. In addition, while GeTe has a cubic structure above 700 K, the local atomic disorder persists, which maintains its low thermal conductivity. To date, the understanding of the temperature‐dependent thermoelectric properties of cubic GeTe at room temperature and above is very limited. This is due to the difficulties in stabilizing cubic GeTe at low temperatures. In this work, we leverage on low level of Ti doping to stabilize cubic‐phase GeTe at room temperature and elucidate its temperature‐dependent electronic and thermal properties. Further doping with In, Cu, Sb, and Pb results in zT as high as 2 at 773 K, and high average zT of 1.4 between 300 and 800 K.

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Al–Si Alloy as a Diffusion Barrier for GeTe-Based Thermoelectric Legs with High Interfacial Reliability and Mechanical Strength

Cited by 25 publications

References 46 publications

Boron Strengthened GeTe‐Based Alloys for Robust Thermoelectric Devices with High Output Power Density

Boron Strengthened GeTe‐Based Alloys for Robust Thermoelectric Devices with High Output Power Density

Realizing a 14% single-leg thermoelectric efficiency in GeTe alloys

Realizing zT Values of 2.0 in Cubic GeTe

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