High Thermoelectric Performance in the Wide Band‐Gap AgGa1‐xTe2 Compounds: Directional Negative Thermal Expansion and Intrinsically Low Thermal Conductivity

Su, Xianli; Zhao, Na; Hao, Shiqiang; Stoumpos, Constantinos C.; Liu, Mengyuan; Chen, Haijie; Xie, Hongyao; Zhang, Qingjie; Wolverton, Chris; Tang, Xinfeng; Kanatzidis, Mercouri G.

doi:10.1002/adfm.201806534

Cited by 73 publications

(57 citation statements)

References 81 publications

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“…However, because of the lower κ L, it shows better TE performance than KAgSe monolayer. The p‐type ZT at 700 K reaches an ultrahigh value of 2.08, which is significantly higher than those of recently reported promising nanoscale TE materials (0.025, 0.45, and 0.63 for SnSe nanosheets, single‐layer Bi 2 Se 3 , and Tellurium nanofilms) [ 36,37,39 ] and Ag‐based bulk TE materials (0.7, 0.85, and 0.9 for CsAg 5 Te 3 , Ag 8 SnSe 6 , and AgBi 3 S 5 , respectively) [ 40–44 ] (Figure 5g). More importantly, such a high ZT, only realized in bulk SnSe (2.6 ± 0.3) [ 45 ] and microscale Ge‐alloyed SnSe (≈2.1), [ 46 ] will be of important practical significance for nanoscale TE applications.…”

Section: Resultsmentioning

confidence: 77%

High ZT 2D Thermoelectrics by Design: Strong Interlayer Vibration and Complete Band‐Extrema Alignment

Zhang

Liu

Tao

et al. 2020

Adv Funct Materials

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The discovery of a record high figure of merit (ZT) of ≈2.6 associated with bulk SnSe has stimulated considerable enthusiasm in searching for 2D systems with similar high ZT. However, previously reported 2D thermoelectric (TE) materials generally possess very low ZT due to the high lattice thermal conductivity (κ L ) and/or small power factor (PF). Herein, a very high ZT (≈2.08) value associated with atomically thin 2D KAgSe nanosheet is reported, which also exhibits an unprecedented low intrinsic κ L (≈0.03 Wm −1 K −1 at 700 K for trilayer) and fairly large PF. The low κ L mainly stems from the high lattice anharmonicity induced by both the "interfacial shear slip" vibrations and the asymmetric "AgSe pair" vibrations from distorted AgSe 4 tetrahedrons. Meanwhile, the complete band-extrema alignment and coexistence of heavy and light bands result in an optimal Seebeck coefficient and electrical conductivity, thereby a large PF. This work suggests not only an alternative way to acquiring high lattice anharmonicity but also a highly competitive 2D TE candidate for wide applications.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adfm.202001200.devices, recently much attention has been devoted to the development of 2D highefficiency TE materials with controllable thickness. [5][6][7] In general, the TE efficiency is characterized by the dimensionless figure of merit ZT = S 2 σT/(κ L + κ e ), where S, σ, T, κ L , and κ e are Seebeck coefficient, electrical conductivity, absolute temperature, lattice thermal conductivity and electronic thermal conductivity, respectively. Apparently, the high TE efficiency can be achieved by increasing the power factor (PF = S 2 σ) together with suppressing the sum of thermal conductivity (κ L + κ e ).Currently, the TE efficiency can be improved by two approaches: i) Tuning effective mass to improve the electronic transport and ii) increasing phonon scattering to suppress the lattice thermal transport. [8][9][10][11] For a given carrier concentration, a large carrier effective mass (m*) contributes to a large S, and the m* is proportional to the band effective mass (m b *) according to m* = N V 2/3 m b *, where N V refers to the band degeneracy. [10,12] A large m b *, however, will reduce the carrier mobility μ since m b 1/ * 2 µ ∝ (2D systems). [13][14][15][16] Hence, to optimize S 2 σ, it is important to attain high N V and moderate m b * simultaneously. A high N V can be achieved either by mixing two types of low-symmetric compounds into a reconstructed highly symmetric structure or by alloying/doping to converge different bands in the Brillouin zone. [8,[17][18][19] For electronic bands at the band edge, a moderate m b * can be realized in principle through element doping or strain engineering. [20] However, in practice, many compounds have limited doping capability and are easily damaged by strain; and the crystal symmetry of the reconstructed structure is uncontrollable. Regarding increasing phonon scattering, intro...

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Section: Resultsmentioning

confidence: 77%

High ZT 2D Thermoelectrics by Design: Strong Interlayer Vibration and Complete Band‐Extrema Alignment

Zhang

Liu

Tao

et al. 2020

Adv Funct Materials

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“…In this estimation, however, the average of the speed of sound ( ν m ) is used. Therefore, the κ min of AgInTe 2 (~0.11 WK −1 m −1 ) can be easily deduced from the κ min value (0.18~0.23 WK −1 m −1 ) of AgGaTe 2 7 , by using the ν m (1240 m/s) and Debye temperature Θ D (156 K) of AgInTe 2 and ν m (2402 m/s) and Θ D (192 K) of AgGaTe 2 7 . The ultralow lattice part in Ag 1- x InTe 2 is largely attributed to the enhanced phonon scattering on the point defects due to the increased concentration of the silver vacancy (V Ag ).…”

Section: Resultsmentioning

confidence: 99%

“…On the other hand, the Debye temperature ( Θ D ) and average sound velocity of AgInTe 2 are 113–202 K and ν age = 1240 ms −1 respectively 11,14,15 , which are very low compared to those of CuInTe 2 ( Θ D = 197.5 K; ν age = 3420 ms −1 ) 16 and CuGaTe 2 ( Θ D = 229.0 K; ν s = 2072.0 ms −1 , ν l = 3817.0 ms −1 ) 1 . Besides that, the average sound velocity is only about half that of AgGaTe 2 ( ν s = 1812.0 ms −1 , ν l = 2990.0 ms −1 ) 7 . It implies that the compound AgInTe 2 , naturally, has a low lattice thermal conductivity 17 , hence it is potentially a good TE candidate.…”

Section: Introductionmentioning

confidence: 93%

“…Therefore, it is quite necessary to explore novel TE candidates. Ternary I-III-VI 2 (I = Cu, Ag; III = Al, Ga, In; VI = S, Se, Te) chalcogenides, such as CuGaTe 2 1 , CuInTe 2 2 , AgInSe 2 3 and AgGaTe 2 4,5 , have recently attracted much attention in thermoelectrics because of their unique crystal and band structures 6,7 , among which the cation vacancy and crystal structure are two important factors in engineering both the carrier concentration and phonon transport 8–10 . However, to our best knowledge, AgInTe 2 has not received due recognition.…”

Section: Introductionmentioning

confidence: 99%

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Silver vacancy concentration engineering leading to the ultralow lattice thermal conductivity and improved thermoelectric performance of Ag1-xInTe2

Zhong

Luo

Xie

et al. 2019

Sci Rep

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AgInTe2 compound has not received enough recognition in thermoelectrics, possibly due to the fact that the presence of Te vacancy (VTe) and antisite defect of In at Ag site (InAg) degrades its electrical conductivity. In this work, we prepared the Ag1-xInTe2 compounds with substoichiometric amounts of Ag and observed an ultralow lattice thermal conductivity (κL = 0.1 Wm−1K−1) for the sample at x = 0.15 and 814 K. This leads to more than 2-fold enhancement in the ZT value (ZT = 0.62) compared to the pristine AgInTe2. In addition, we have traced the origin of the untralow κL using the Callaway model. The results attained in this work suggest that the engineering of the silver vacancy (VAg) concentration is still an effective way to manipulate the thermoelectric performance of AgInTe2, realized by the increased point defects and modified crystal structure distortion as the VAg concentration increases.

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“…4b is the temperature-dependent electrical conductivities (s), which increase with temperature until at $730 K. Above $730 K, the materials exhibit metallic-like behavior, as was observed in AgGa 1Àx Te 2 system. 46 Besides, it is noted that the electrical conductivity at $822 K increases from 5.7 Â 10 3 U À1 m À1 (x ¼ 0, V c ¼ 0.11) to 11.4 Â 10 3 U À1 m À1 (x ¼ 0.3, V c ¼ 0.078) before it starts to fall to the 8.7 Â 10 3 U À1 m À1 (x ¼ 0.4, V c ¼ 0.067), which corresponds to the variations in carrier concentration and mobility (Fig. 3).…”

Section: Transport and Te Performancementioning

confidence: 99%

Co-regulation of the copper vacancy concentration and point defects leading to the enhanced thermoelectric performance of Cu₃In₅Te₉-based chalcogenides

Luo

et al. 2019

RSC Adv.

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High Thermoelectric Performance in the Wide Band‐Gap AgGa_1‐_xTe₂ Compounds: Directional Negative Thermal Expansion and Intrinsically Low Thermal Conductivity

Cited by 73 publications

References 81 publications

High ZT 2D Thermoelectrics by Design: Strong Interlayer Vibration and Complete Band‐Extrema Alignment

High ZT 2D Thermoelectrics by Design: Strong Interlayer Vibration and Complete Band‐Extrema Alignment

Silver vacancy concentration engineering leading to the ultralow lattice thermal conductivity and improved thermoelectric performance of Ag1-xInTe2

Co-regulation of the copper vacancy concentration and point defects leading to the enhanced thermoelectric performance of Cu₃In₅Te₉-based chalcogenides

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High Thermoelectric Performance in the Wide Band‐Gap AgGa1‐xTe2 Compounds: Directional Negative Thermal Expansion and Intrinsically Low Thermal Conductivity

Cited by 73 publications

References 81 publications

High ZT 2D Thermoelectrics by Design: Strong Interlayer Vibration and Complete Band‐Extrema Alignment

High ZT 2D Thermoelectrics by Design: Strong Interlayer Vibration and Complete Band‐Extrema Alignment

Silver vacancy concentration engineering leading to the ultralow lattice thermal conductivity and improved thermoelectric performance of Ag1-xInTe2

Co-regulation of the copper vacancy concentration and point defects leading to the enhanced thermoelectric performance of Cu3In5Te9-based chalcogenides

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High Thermoelectric Performance in the Wide Band‐Gap AgGa_1‐_xTe₂ Compounds: Directional Negative Thermal Expansion and Intrinsically Low Thermal Conductivity

Co-regulation of the copper vacancy concentration and point defects leading to the enhanced thermoelectric performance of Cu₃In₅Te₉-based chalcogenides