Microstructure‐Lattice Thermal Conductivity Correlation in Nanostructured PbTe<sub>0.7</sub>S<sub>0.3</sub> Thermoelectric Materials

He, Jiaqing; Girard, Steven N.; Kanatzidis, Mercouri G.; Dravid, Vinayak P.

doi:10.1002/adfm.200901905

Cited by 307 publications

(272 citation statements)

References 47 publications

(54 reference statements)

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“…These results denote that phonon scattering has occurred due to disorder rising from solute atoms in solid solution as discussed above, and also through interfaces of the lamellar pattern. Although the interlamellar spacing has been increased by equilibration at high temperatures, compared to previous studies, 17 phonon scattering by boundaries and interfaces played a significant role in the thermal conductivity reduction.…”

Section: Transport Propertiesmentioning

confidence: 84%

“…Recent studies 7-9 11 12 have improved PbTe thermoelectric performance significantly through tuning the electronic structure and/or nanostructuring of bulk materials. However, Te is rare in the Earth's crust, used in other applications 13 and is expensive hence the focus in the latest studies [14][15][16][17] trying to replace Te with Se or S. 18 19 Sulphur is amongst the 16 most abundant elements in the Earth's crust 13 and replacing Te, partially with S also provides a fascinating opportunity to form fine lamellar microstructure through spinodal decomposition, which appears in binary phase diagrams of the PbTe-PbS system. Lamellar patterns resembling a eutectic structure have been demonstrated for several thermoelectric materials 17 20-22 and thermal conductivity reduction has been reported, specifically for PbTe-PbS system, 14 …”

Section: Introductionmentioning

confidence: 99%

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Thermoelectric performance of tellurium-reduced quaternary p-type lead–chalcogenide composites

et al. 2014

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PbTe is a premiere mid-range temperature thermoelectric material and recent studies have proven nanostructing as an effective approach to reduce thermal conductivity of alloys. Whereas, little attention has been given to long-term thermal stability of secondary phases and microstructural evolution. Interestingly, replacing Te with S in PbTe provides an opportunity to form nanostructures in the bulk material through spinodal decomposition, which appears in binary phase diagrams of the PbTe-PbS system. Herein, the critical composition of PbTe 0.38 S 0.62 alloy is fabricated to n-type by chlorine doping. Thermoelectric transport properties of the alloy are investigated in the 300-850 K temperature range and the maximum zT achieved at 800 K is 0.75 with a predicted zT ∼ 0.85 at 750 K from single parabolic band model. The microstructure of the sintered samples was studied by FEG-SEM for both the as sintered and post transport properties measurement. The experimental results are compared with estimates from the parallel and series models for heterogeneous composites of single phase PbTe and PbS. The Seebeck coefficient is in agreement with the models predictions, but the resistivity is higher and the thermal conductivity is much lower than predicted values. We propose that this is attributed to the phonon and electron scattering on solute atoms in solid solutions and at interfaces.

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Section: Transport Propertiesmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Thermoelectric performance of tellurium-reduced quaternary p-type lead–chalcogenide composites

et al. 2014

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“…Most of the recent experimental studies on the strong reduction of the lattice thermal conductivity in nanostructured PbTe [9,10] emphasized the importance of dislocations, nanoscale precipitates and strain while pointing out that the mere presence of nanostructuring cannot sufficiently increase the phonon scattering. He et al [11] found that not all nanostructures favorably scatter phonons.…”

Section: Introductionmentioning

confidence: 99%

“…Significant efforts have been made to enhance the zT value of PbTe [2][3][4][5][6][7][8][9][10][11]. By introducing resonant states, Tl doped p-type PbTe resulted in a high zT value of 1.5 at 773 K [4].…”

Section: Introductionmentioning

confidence: 99%

Phonon conduction in PbSe, PbTe, and PbTe1−xSexfrom first-principles calculations

et al. 2012

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We apply first-principles calculations to lead selenide (PbSe) and lead telluride (PbTe) and their alloys (PbTe 1-x Se x ) which are potentially good thermoelectric materials, to investigate their phonon transport properties. By accurately reproducing the lattice thermal conductivity, we validate the approaches adopted in this work. We then compare and contrast PbSe and PbTe, evaluate the importance of the optical phonons to lattice thermal conductivity, and estimate the impacts of nanostructuring and alloying on further reducing the lattice thermal conductivity. The results indicate that: 1) the optical phonons are important not only because they directly comprise over 20% of the lattice thermal conductivity, but also because they provide strong scattering channels for acoustic phonons, which is crucial for the low thermal conductivity; 2) nanostructures of less than ~10 nm are needed to reduce the lattice thermal conductivity for pure PbSe and PbTe; 3) alloying should be a relatively effective way to reduce the lattice thermal conductivity.

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“…[13][14][15][16] Ternary PbTe-rich alloys of PbTe-PbSe 4,17,18 show a higher figure of merit than individual binary PbTe and PbSe systems in the temperature range of 550-800 K, mainly due to alteration of the electronic band structure. 4,18 In contrast, higher zT values of PbTe-PbS [19][20][21][22] compared to the binary systems are credited to the reduction in lattice thermal conductivity, which originates from phonon scattering at the interfaces of secondary phases, as PbS shows very limited solubility in the PbTe matrix. 23 Here, we present a strategy to design single-phase quaternary alloys with high thermoelectric efficiency.…”

Section: Introductionmentioning

confidence: 99%

Chemical composition tuning in quaternary p-type Pb-chalcogenides – a promising strategy for enhanced thermoelectric performance

Yamini

Wang

Gibbs

et al. 2014

Phys. Chem. Chem. Phys.

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Recently a significant improvement in the thermoelectric performance of p-type ternary PbTe-PbSe and PbTe-PbS systems has been realized through alternating the electronic band structure and introducing nano-scale precipitates to bulk materials respectively. However, the quaternary system of PbTe-PbSe-PbS has received less attention. In the current work, we have excluded phase complexity by fabricating single phase sodium doped PbTe, alloyed with PbS up to its solubility limit which is extended to larger concentrations than in the ternary system of PbTe-PbS due to the presence of PbSe. We have presented a thermoelectric efficiency of approximately 1.6 which is superior to ternary PbTe-PbSe and PbTe-PbS at similar carrier concentrations and the binary PbTe, PbSe and PbS alloys. The quaternary system shows a larger Seebeck coefficient than the ternary PbTe-PbSe alloy, indicative of a wider band gap, valence band energy offset and heavier carriers effective mass. In addition, the existence of PbS in the alloy further reduces the lattice thermal conductivity originated from phonon scattering on solute atoms with high contrast atomic mass. Single phase quaternary PbTe-PbSe-PbS alloys are promising thermoelectric materials that provide high performance through adjusting the electronic band structure by regulating chemical composition.

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Microstructure‐Lattice Thermal Conductivity Correlation in Nanostructured PbTe_0.7S_0.3 Thermoelectric Materials

Cited by 307 publications

References 47 publications

Thermoelectric performance of tellurium-reduced quaternary p-type lead–chalcogenide composites

Thermoelectric performance of tellurium-reduced quaternary p-type lead–chalcogenide composites

Phonon conduction in PbSe, PbTe, and PbTe1−xSexfrom first-principles calculations

Chemical composition tuning in quaternary p-type Pb-chalcogenides – a promising strategy for enhanced thermoelectric performance

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Microstructure‐Lattice Thermal Conductivity Correlation in Nanostructured PbTe0.7S0.3 Thermoelectric Materials

Cited by 307 publications

References 47 publications

Thermoelectric performance of tellurium-reduced quaternary p-type lead–chalcogenide composites

Thermoelectric performance of tellurium-reduced quaternary p-type lead–chalcogenide composites

Phonon conduction in PbSe, PbTe, and PbTe1−xSexfrom first-principles calculations

Chemical composition tuning in quaternary p-type Pb-chalcogenides – a promising strategy for enhanced thermoelectric performance

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Microstructure‐Lattice Thermal Conductivity Correlation in Nanostructured PbTe_0.7S_0.3 Thermoelectric Materials