Enhancement of Thermoelectric Properties in Pd–In Co-Doped SnTe and Its Phase Transition Behavior

Ma, Zheng; Lei, Jingdan; Zhou, Xiaoyuan; Wang, Chao; Wang, Jianli; Cheng, Zhenxiang; Wang, Yuanxu

doi:10.1021/acsami.9b08564

Cited by 33 publications

(37 citation statements)

References 59 publications

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“…Synthesis: The SnTe-based samples were synthesized via a vacuumsealed tube melt processing route. It must be noted that, just like in many other SnTe-based materials that are reported so far, the selfcompensated Sn 1.03-x M x Te (M = dopant) nominal composition was adopted here to reach the actual stoichiometry and to optimize their charge carrier concentration, [37,40,59,64,79,86] that is, to compensate for the inherent nature of SnTe to have Sn vacancies (Sn 1−x Te). From the crystallographic point of view, it was not possible to have excess Sn in the structure (SnTe).…”

Section: Methodsmentioning

confidence: 99%

“…Though not common, such a phenomenon has been reported in the past for SnTe-based materials. [54,64,93] With the incorporation of Ti/Zr/Mn in SnTe, the red shift/low-frequency shift in the Raman spectra conveys that the force constant of the bonds around the Te site is reduced or the chemical bond is notably softened, as the bond stiffness is inversely proportional to bond length. This softening effect can well explain the reason for decreased lattice thermal conductivity when Ti/Zr or Ti-Mn/Zr-Mn are doped to SnTe.…”

Section: Lattice Softening-perspectives From Raman Analysismentioning

confidence: 99%

“…Total energy convergence was achieved with a Brillouin zone (BZ) integration mesh of 500 k-points. Supercells of size 2×2×2 consisting of 64 ) were considered, in a way such that they closely represent the experimental compositions. For the purpose of simplicity, though there are some magnetic interactions in the doped samples, the magnetic contribution was not considered in these computations.…”

Section: Supporting Informationmentioning

confidence: 99%

“…To further support this fact, when the TE properties of pristine SnTe from this work (which contains Sn impurity phase) is compared with some literature reports where they do not detect any Sn secondary phase, their transport properties are quite comparable. [48,64,65]…”

Section: Structure and Transport Properties Of Ti-mn And Zr-mn Codoped Snte Compoundsmentioning

confidence: 99%

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Physical Insights on the Lattice Softening Driven Mid‐Temperature Range Thermoelectrics of Ti/Zr‐Inserted SnTe—An Outlook Beyond the Horizons of Conventional Phonon Scattering and Excavation of Heikes’ Equation for Estimating Carrier Properties

Muchtar

Srinivasan

Tonquesse

et al. 2021

Advanced Energy Materials

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Most of the best known SnTe‐based materials exhibit an attractive thermoelectric figure of merit (zT) only at the high‐temperature regime, but their performance at the low‐mid temperature ranges is quite uninspiring, and this discordance necessitates a large temperature gradient (∆T ≥ 550 K) to effectuate a reasonable efficiency, η. Here, the transition elements, Ti and Zr, that have not been used in the past are tried as dopants for SnTe and an enhanced device/average zT and/or η are reported with a lower ∆T ≈ 400 K and without the requisite for a stupendous peak/maximum zT. This notable performance emanates from—i) improved weighted mobility by optimally balancing between effective mass, carrier concentration, and mobility, ii) coupling of charge carriers with magnetic entropy, and the paramount factor being the iii) weakening of the chemical bonds (lattice softening). The thermal damping caused by lattice softening affects the phonon group velocity and the elastic properties, and the resultant increase in the degree of anharmonicity and the high density of internal strain‐fields, along with the phonon scattering effects, play an active role in tuning the overall thermoelectric performance. This work also excavates/opens up the discussion of applying the Heikes’ equation to qualitatively compare the trend of charge carriers for a given thermoelectric material system.

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Section: Methodsmentioning

confidence: 99%

Section: Lattice Softening-perspectives From Raman Analysismentioning

confidence: 99%

Section: Supporting Informationmentioning

confidence: 99%

Section: Structure and Transport Properties Of Ti-mn And Zr-mn Codoped Snte Compoundsmentioning

confidence: 99%

See 2 more Smart Citations

Physical Insights on the Lattice Softening Driven Mid‐Temperature Range Thermoelectrics of Ti/Zr‐Inserted SnTe—An Outlook Beyond the Horizons of Conventional Phonon Scattering and Excavation of Heikes’ Equation for Estimating Carrier Properties

Muchtar

Srinivasan

Tonquesse

et al. 2021

Advanced Energy Materials

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“…However, the high toxicity of Pb limits its practical application. Alternatively, κ l of SnTe is relatively higher which leads to lower zT value of only 1.51 at 800 K [23] comparing with PbTe [18] and GeTe [24]. Therefore, nontoxic and highperformance GeTe-based thermoelectric materials, with the peak zT values higher than 2 [24,25], have attracted extensive attention.…”

Section: Introductionmentioning

confidence: 99%

Rare-Earth Nd Inducing Record-High Thermoelectric Performance of (GeTe) ₈₅ (AgSbTe ₂ ) ₁₅

et al. 2021

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As a promising midtemperature thermoelectric material with both higher thermoelectric performance and mechanical property, Tellurium Antimony Germanium Silver (TAGS-x), written as (GeTe)x(AgSbTe2)1-x, especially (GeTe)0.85(AgSbTe2)0.15 (TAGS-85), has attracted wide attention. Herein, we innovatively use Nd doping to synergistically decrease the carrier concentration to the optimal level leading to enhanced dimensionless figure of merit, zT. Our density-functional theory calculation results indicate that Nd-doping reduced carrier concentration should be attributed to the enlargement of band gap. The optimized carrier concentration results in an ultrahigh power factor of ~32 μW cm-1 K-2 at 727 K in Ge0.74Ag0.13Sb0.11Nd0.02Te. Simultaneously, the lattice thermal conductivity of Ge0.74Ag0.13Sb0.11Nd0.02Te retained as low as ~0.5 at 727 K. Ultimately, a record-high zT of 1.65 at 727 K is observed in the Ge0.74Ag0.13Sb0.11Nd0.02Te. This study indicates rare-earth Nd doping is effective in boosting the thermoelectric performance of TAGS-85 and approached a record-high level via synergistic effect.

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High Entropy Semiconductor AgMnGeSbTe₄ with Desirable Thermoelectric Performance

et al. 2021

Adv Funct Materials

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A new p-type high entropy semiconductor AgMnGeSbTe 4 with a band gap of ≈0.28 eV is reported as a promising thermoelectric material. AgMnGeSbTe 4 crystallizes in the rock-salt NaCl structure with cations Ag, Mn, Ge, and Sb randomly disordered over the Na site. Thus, a strong lattice distortion forms from the large difference in the atomic radii of Ag, Mn, Ge, and Sb, resulting in a low lattice thermal conductivity of 0.54 W m −1 K −1 at 600 K. In addition, the AgMnGeSbTe 4 exhibits a degenerate semiconductor behavior and a large average power factor of 10.36 µW cm −1 K −2 in the temperature range of 400-773 K. As a consequence, the AgMnGeSbTe 4 has a peak figure of merit (ZT) of 1.05 at 773 K and a desirable average ZT value of 0.84 in the temperature range of 400-773 K. Moreover, the thermoelectric performance of AgMnGeSbTe 4 can be further enhanced by precipitating of Ag 8 GeTe 6 , which acts as extra scatting centers for holes with low energy and phonons with medium wavelength. The simultaneous optimization in power factor and lattice thermal conductivity yields a peak ZT of 1.27 at 773 K and an average ZT of 0.92 (400-773 K) in AgMnGeSbTe 4 -1 mol% Ag 8 GeTe 6 .

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Enhancement of Thermoelectric Properties in Pd–In Co-Doped SnTe and Its Phase Transition Behavior

Cited by 33 publications

References 59 publications

Physical Insights on the Lattice Softening Driven Mid‐Temperature Range Thermoelectrics of Ti/Zr‐Inserted SnTe—An Outlook Beyond the Horizons of Conventional Phonon Scattering and Excavation of Heikes’ Equation for Estimating Carrier Properties

Physical Insights on the Lattice Softening Driven Mid‐Temperature Range Thermoelectrics of Ti/Zr‐Inserted SnTe—An Outlook Beyond the Horizons of Conventional Phonon Scattering and Excavation of Heikes’ Equation for Estimating Carrier Properties

Rare-Earth Nd Inducing Record-High Thermoelectric Performance of (GeTe) ₈₅ (AgSbTe ₂ ) ₁₅

High Entropy Semiconductor AgMnGeSbTe₄ with Desirable Thermoelectric Performance

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Enhancement of Thermoelectric Properties in Pd–In Co-Doped SnTe and Its Phase Transition Behavior

Cited by 33 publications

References 59 publications

Physical Insights on the Lattice Softening Driven Mid‐Temperature Range Thermoelectrics of Ti/Zr‐Inserted SnTe—An Outlook Beyond the Horizons of Conventional Phonon Scattering and Excavation of Heikes’ Equation for Estimating Carrier Properties

Physical Insights on the Lattice Softening Driven Mid‐Temperature Range Thermoelectrics of Ti/Zr‐Inserted SnTe—An Outlook Beyond the Horizons of Conventional Phonon Scattering and Excavation of Heikes’ Equation for Estimating Carrier Properties

Rare-Earth Nd Inducing Record-High Thermoelectric Performance of (GeTe) 85 (AgSbTe 2 ) 15

High Entropy Semiconductor AgMnGeSbTe4 with Desirable Thermoelectric Performance

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Product

Resources

About

Rare-Earth Nd Inducing Record-High Thermoelectric Performance of (GeTe) ₈₅ (AgSbTe ₂ ) ₁₅

High Entropy Semiconductor AgMnGeSbTe₄ with Desirable Thermoelectric Performance