Microstructure Evolution of Ag-Alloyed PbTe-Based Compounds and Implications for Thermoelectric Performance

Grossfeld, Tom; Sheskin, Ariel; Gelbstein, Yaniv; Amouyal, Yaron

doi:10.3390/cryst7090281

Cited by 14 publications

(23 citation statements)

References 41 publications

(60 reference statements)

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“…10 20 m −3 upon 6 h aging, which decreases down to ∼10 19 m −3 after 48 h aging. 20 This trend was associated with the nucleation of Ag 2 Te precipitates for relatively short aging times, followed by their coarsening observed for longer times. Alongside this microstructure evolution, κ l reaches a minimum value as low as 0.4 W m −1 K −1 at 500 °C upon 6 h aging at 380 °C due to intensive phonon scattering by a high number of precipitates, which increases up to 1.2 W m −1 K −1 upon aging for longer times.…”

Section: Introductionmentioning

confidence: 95%

Tailoring Thermoelectric Transport Properties of Ag-Alloyed PbTe: Effects of Microstructure Evolution

Sheskin

Schwarz

et al. 2018

ACS Appl. Mater. Interfaces

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Capturing and converting waste heat into electrical power through thermoelectric generators based on the Seebeck effect is a promising alternative energy source. Among thermoelectric compounds, PbTe can be alloyed and form precipitates by aging at elevated temperatures, thus reducing thermal conductivity by phonon scattering. Here, PbTe is alloyed with Ag to form Ag-rich precipitates having a number density controlled by heat treatments. We employ complementary scanning transmission electron microscopy and atom probe tomography to analyze the precipitate number density and the PbTe− matrix composition. We measure the temperature-dependent transport coefficients and correlate them with the microstructure. The thermal and electrical conductivities, as well as the Seebeck coefficients, are found to be highly sensitive to the microstructure and its temporal evolution, e.g., the number density of Ag-rich precipitates increases by ca. 3 orders of magnitude and reaches (1.68 ± 0.92) × 10 24 m −3 upon aging at 380 °C for 6 h, which is pronounced by reduction in thermal conductivity to a value as low as 0.85 W m −1 K −1 at 300 °C. Our findings will help to guide predictive tools for further design of materials for energy harvesting.

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Section: Introductionmentioning

confidence: 95%

Tailoring Thermoelectric Transport Properties of Ag-Alloyed PbTe: Effects of Microstructure Evolution

Sheskin

Schwarz

et al. 2018

ACS Appl. Mater. Interfaces

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“…This follows a rough estimate based on the Callaway model, as well as on a quantitative model for phonon transport in heterogeneous media superimposing the phonon DOS with the precipitates’ size distribution, which is tested for PbTe using the Debye temperature, sound velocity, and phonon DOS as inputs from DFT . It is found that

κ_{l}

of these Ag‐alloyed PbTe‐based compounds is reduced by controlled nucleation of Ag 2 Te precipitates, exhibiting a number density value as high as 2.7·10 20 m −3 upon 6 h aging at 380 °C, as shown in Figure . This yields a TE figure of merit value of approx.…”

Section: Phase Separationmentioning

confidence: 99%

“…An interesting system exhibiting Widmanstätten Sb 2 Te 3 precipitates residing in a PbTe matrix was thoroughly investigated by Ikeda et al., including all evolution stages of nucleation, growth, and coarsening, with implications for microstructure manipulations to control TE transport coefficients . The phase separation approach is well‐demonstrated for Ag‐alloyed PbTe systems, where doping with 3.3–5.0 at.% Ag results in nucleation of the Ag 2 Te phase in the form of precipitates with different N v values upon aging heat treatments . Particularly for PbTe‐based compounds, N v values adequately larger than 10 20 m −3 are required to initiate effective scattering of acoustic phonons.…”

Section: Phase Separationmentioning

confidence: 99%

Physical Metallurgy Inspired Nano‐Features for Enhancement of Thermoelectric Conversion Efficiency

Amouyal

Gelbstein

Fuks

2018

Advcd Theory and Sims

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Thermoelectric (TE) materials are useful for the conversion of heat flux into electrical power and for heat removal and are, therefore, technologically important. Development of TE materials involves controlling their thermal and electrical transport, and both are sensitive to the finest features of the material microstructure. Major turning points recorded in TE material research are enabled due to adopting concepts from physical metallurgy. These classical approaches, originally developed to explain plastic deformation mechanisms in metallic systems, are now being employed to elucidate thermal and electrical transport in highly efficient TE materials, and serve as tools to manipulate their transport properties. The present Progress Report reviews recent studies combining experimental and computational approaches aiming to elucidate the role of 0D, 1D, 2D, and 3D lattice defects, and to harness them to enhance TE performance.

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“…For single‐phase compounds, this may occur due to the introduction of low energy, non‐dispersive impurity modes into the phonon spectra that significantly impact the propagation of acoustic phonons; this effect is not additive with respect to the impurity concentration in the compound. For two‐phase TE compounds, such non‐monotonous behavior is associated with an entirely different factor, that is, the dual effect of doping atoms as forming agents of both substitutional point defects and nucleation of second‐phase precipitates; when both factors interplay, non‐monotonous trend of κ L occurs . It turns out that this approach of alloying with other elements to modify κ L sometimes yields unpredictable results, rendering the effective manipulation of κ L as a very challenging task that requires deep understanding of atomistic mechanisms enabling dissipation of the energy carried by phonons.…”

Section: Introductionmentioning

confidence: 99%

On the Influence of Rare Earth Dopants on Thermal Transport in Thermoelectric Bi₂Te₃ Compounds: An Ab Initio Perspective

Baranovskiy

Harush

Amouyal

2019

Advcd Theory and Sims

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A density functional theory (DFT) study of thermal transport properties of rare earth (RE) doped Bi 2 Te 3 compounds (RE = Y, La, Eu, Gd, and Lu) is reported. The calculations reveal strong nonmonotonous concentration dependence of the lattice thermal conductivity (κ L ) with local minimum in the region of 2-3 at.% dopant concentration for all dopants in the series except Eu. This behavior is associated with the presence of impurity phonon modes in the frequency range of 0-2 THz. The low-frequency parts of the phonon spectra vary substantially for different divalent and trivalent RE dopants, which results in different phonon scattering events for different dopants. The concentration dependence of κ L correlates with both Grüneisen parameter (γ ) and sound velocity (v). This provides us with a simple and powerful predictive tool assessing thermal transport in RE-doped Bi 2 Te 3 compounds.

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Microstructure Evolution of Ag-Alloyed PbTe-Based Compounds and Implications for Thermoelectric Performance

Cited by 14 publications

References 41 publications

Tailoring Thermoelectric Transport Properties of Ag-Alloyed PbTe: Effects of Microstructure Evolution

Tailoring Thermoelectric Transport Properties of Ag-Alloyed PbTe: Effects of Microstructure Evolution

Physical Metallurgy Inspired Nano‐Features for Enhancement of Thermoelectric Conversion Efficiency

On the Influence of Rare Earth Dopants on Thermal Transport in Thermoelectric Bi₂Te₃ Compounds: An Ab Initio Perspective

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Microstructure Evolution of Ag-Alloyed PbTe-Based Compounds and Implications for Thermoelectric Performance

Cited by 14 publications

References 41 publications

Tailoring Thermoelectric Transport Properties of Ag-Alloyed PbTe: Effects of Microstructure Evolution

Tailoring Thermoelectric Transport Properties of Ag-Alloyed PbTe: Effects of Microstructure Evolution

Physical Metallurgy Inspired Nano‐Features for Enhancement of Thermoelectric Conversion Efficiency

On the Influence of Rare Earth Dopants on Thermal Transport in Thermoelectric Bi2Te3 Compounds: An Ab Initio Perspective

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On the Influence of Rare Earth Dopants on Thermal Transport in Thermoelectric Bi₂Te₃ Compounds: An Ab Initio Perspective