High thermoelectric conversion efficiency of MgAgSb-based material with hot-pressed contacts

Kraemer, Daniel; Sui, Jiehe; McEnaney, Kenneth; Zhao, Huaizhou; Qi, Jie; Ren, Zhifeng; Chen, Gang

doi:10.1039/c4ee02813a

Cited by 177 publications

(145 citation statements)

References 28 publications

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“…[ 35 ] More importantly, n-type Mg 2 (Si, Sn) exhibits a high power factor and average ZT from 300 to 548 K along with a modest thermomechanical properties, [ 10,70 ] it is promising to pair p-type MgAgSb with n-type Mg 2 (Si, Sn) when the suitable contacts are found for Mg 2 (Si, Sn) from the current view. Since n-type Mg 2 (Si, Sn) has a low resistivity ≈7 × 10 −6 Ω m at 300 K, [ 10 ] lower resistivity by Li doping [ 33,34,36 ] wileyonlinelibrary.…”

Section: Tuning the Carrier Concentration Via LI Dopingmentioning

confidence: 98%

Lithium Doping to Enhance Thermoelectric Performance of MgAgSb with Weak Electron–Phonon Coupling

Liu

Wang

Mao

et al. 2016

Advanced Energy Materials

132

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Despite the unfavorable band structure with twofold degeneracy at the valence band maximum, MgAgSb is still an excellent p‐type thermoelectric material for applications near room temperature. The intrinsically weak electron–phonon coupling, reflected by the low deformation potential Edef ≈ 6.3 eV, plays a crucial role in the relatively high power factor of MgAgSb. More importantly, Li is successfully doped into Mg site to tune the carrier concentration, leading to the resistivity reduction by a factor of 3 and a consequent increase in power factor by ≈30% at 300 K. Low lattice thermal conductivity can be simultaneously achieved by all‐scale hierarchical phonon scattering architecture including high density of dislocations and nanoscale stacking faults, nanoinclusions, and multiscale grain boundaries. Collectively, much higher average power factor ≈25 μW cm−1 K−2 with a high average ZT ≈ 1.1 from 300 to 548 K is achieved for 0.01 Li doping, which would result in a high output power density ≈1.56 W cm−2 and leg efficiency ≈9.2% by calculations assuming cold‐side temperature Tc = 323 K, hot‐side temperature Th = 548 K, and leg length = 2 mm.

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Section: Tuning the Carrier Concentration Via LI Dopingmentioning

confidence: 98%

Lithium Doping to Enhance Thermoelectric Performance of MgAgSb with Weak Electron–Phonon Coupling

Liu

Wang

Mao

et al. 2016

Advanced Energy Materials

132

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“…3). 30,32,47 The segmented legs are fabricated by soldering the bismuth telluride and skutterudite elements to each other (Fig. 1b).…”

Section: Methodsmentioning

confidence: 99%

“…26,27 Significant progress has been made on improving and developing new thermoelectric materials in recent years, however actual device demonstrations have been scarce and are mostly motivated by waste heat recovery applications. [28][29][30][31][32][33][34] The auxiliary efficiency in Eq. (1) accounts for possible system parasitic losses such as electricity consumption for pumping and cooling.…”

Section: Csteg Efficiencymentioning

confidence: 99%

Concentrating solar thermoelectric generators with a peak efficiency of 7.4%

et al. 2016

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Concentrating solar power normally employs mechanical heat engines and is thus only used in large-scale power plants; however, it is compatible with inexpensive thermal storage enabling electricity dispatchability. Concentrating solar thermoelectric generators (STEGs) have the advantage of replacing the mechanical power block with a solid-state heat engine based on the Seebeck effect, simplifying the system. The highest reported efficiency of STEGs so far is 5.2%. Here, we report experimental measurements of STEGs with a peak efficiency of 9.6% at an optically concentrated normal solar irradiance of 211 kW m -2 , and a system efficiency of 7.4% after considering optical concentration losses. The performance improvement is achieved by the use of segmented thermoelectric legs, a high-temperature spectrally-selective solar absorber enabling stable vacuum operation with absorber temperatures up to 600°C, and combining optical and thermal concentration. Our work suggests that concentrating STEGs have the potential to become a promising alternative solar energy technology.

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“…One effective approach to enhance ZT is through nanostructuring that can significantly enhance phonon scattering and consequently result in a much lower lattice thermal conductivity compared with that of the unmodified bulk counterpart (2). This approach works well for many inorganic TE materials, such as Bi 2 Te 3 (2), IV-VI semiconductor compounds (3,4), lead-antimony-silver-tellurium (LAST) (5), skutterudites (6), clathrates (7), CuSe 2 (8), Zintl phases (9), half-Heuslers (10-12), MgAgSb (13,14), Mg 2 (Si, Ge, Sn) (15,16), and others.…”

Section: ·Kmentioning

confidence: 99%

Achieving high power factor and output power density in p-type half-Heuslers Nb _1-x Ti _x FeSb

Kraemer

Mao

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

237

152

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Improvements in thermoelectric material performance over the past two decades have largely been based on decreasing the phonon thermal conductivity. Enhancing the power factor has been less successful in comparison. In this work, a peak power factor of ∼106 μW·cm −1 ·K −2 is achieved by increasing the hot pressing temperature up to 1,373 K in the p-type half-Heusler Nb 0.95 Ti 0.05 FeSb. The high power factor subsequently yields a record output power density of ∼22 W·cm −2 based on a single-leg device operating at between 293 K and 868 K. Such a high-output power density can be beneficial for large-scale power generation applications.half-Heusler | thermoelectric | power factor | carrier mobility | output power density T he majority of industrial energy input is lost as waste heat. Converting some of the waste heat into useful electrical power will lead to the reduction of fossil fuel consumption and CO 2 emission. Thermoelectric (TE) technologies are unique in converting heat into electricity due to their solid-state nature. The ideal device conversion efficiency of TE materials is usually characterized by (1)where ZT is the average thermoelectric figure of merit (ZT) between the hot side temperature (T H ) and the cold side temperature (T C ) of a TE material and is defined aswhere PF, T, κ tot , S, σ, κ L , κ e , and κ bip are the power factor, absolute temperature, total thermal conductivity, Seebeck coefficient, electrical conductivity, lattice thermal conductivity, electronic thermal conductivity, and bipolar thermal conductivity, respectively. Higher ZT corresponds to higher conversion efficiency. One effective approach to enhance ZT is through nanostructuring that can significantly enhance phonon scattering and consequently result in a much lower lattice thermal conductivity compared with that of the unmodified bulk counterpart (2). This approach works well for many inorganic TE materials, such as Bi 2 Te 3 (2), IV-VI semiconductor compounds (3, 4), lead-antimony-silver-tellurium (LAST) (5), skutterudites (6), clathrates (7), CuSe 2 (8), Zintl phases (9), half-Heuslers (10-12), MgAgSb (13, 14), Mg 2 (Si, Ge, Sn) (15, 16), and others.However, nanostructuring is effective only when the grain size is comparable to or smaller than the phonon mean free path (MFP). In compounds with a phonon MFP shorter than the nanosized grain diameters, nanostructuring might impair the electron transport more than the phonon transport, thus potentially decreasing the power factor and ZT. In contrast, improving ZT by boosting the power factor has not yet been widely studied (17)(18)(19)(20). To the best of our knowledge, there is no theoretical upper limit applied to the power factor. Additionally, the output power density ω of a device with hot side at T H and cold side at T C is directly related to the power factor by (21)where L is the leg length of the TE material and PF is the averaged power factor over the leg. As contact resistance limits the reduction of length L, higher power factor favors higher power density when h...

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High thermoelectric conversion efficiency of MgAgSb-based material with hot-pressed contacts

Cited by 177 publications

References 28 publications

Lithium Doping to Enhance Thermoelectric Performance of MgAgSb with Weak Electron–Phonon Coupling

Lithium Doping to Enhance Thermoelectric Performance of MgAgSb with Weak Electron–Phonon Coupling

Concentrating solar thermoelectric generators with a peak efficiency of 7.4%

Achieving high power factor and output power density in p-type half-Heuslers Nb _1-x Ti _x FeSb

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High thermoelectric conversion efficiency of MgAgSb-based material with hot-pressed contacts

Cited by 177 publications

References 28 publications

Lithium Doping to Enhance Thermoelectric Performance of MgAgSb with Weak Electron–Phonon Coupling

Lithium Doping to Enhance Thermoelectric Performance of MgAgSb with Weak Electron–Phonon Coupling

Concentrating solar thermoelectric generators with a peak efficiency of 7.4%

Achieving high power factor and output power density in p-type half-Heuslers Nb 1-x Ti x FeSb

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Achieving high power factor and output power density in p-type half-Heuslers Nb _1-x Ti _x FeSb