Enhancement in thermoelectric performance of n-type Pb-deficit Pb-Sb-Te alloys

Srinivasan, Bhuvanesh; Gucci, Francesco; Boussard‐Plédel, Catherine; Cheviré, François; Reece, Michael J.; Tricot, Sylvain; Calvez, Laurent; Bureau, Bruno

doi:10.1016/j.jallcom.2017.09.135

Cited by 22 publications

(19 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Even the idea of semiconducting chalcogenide glasses (based on phonon-glass electron-crystal approach) as potential thermoelectric materials have been tried with varying degree of success. [17][18][19][20] Though the concept of band engineering is extensively applied to various p-and n-type materials like SnTe [21][22][23][24][25] , PbTe [26][27][28] , half-Heuser 29 and Mg2Si 30 , it is applied relatively less on GeTe-based materials.…”

Section: Introductionmentioning

confidence: 99%

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge_1−x−yGa_xSb_yTe via band engineering and hybrid flash-SPS processing

Srinivasan

Gellé

Gucci

et al. 2019

Inorg. Chem. Front.

Self Cite

View full text Add to dashboard Cite

show abstract

Section: Introductionmentioning

confidence: 99%

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge_1−x−yGa_xSb_yTe via band engineering and hybrid flash-SPS processing

Srinivasan

Gellé

Gucci

et al. 2019

Inorg. Chem. Front.

Self Cite

View full text Add to dashboard Cite

show abstract

“…(i) quantum confinement of electron charge carriers; 8 (ii) synergistic nano-structuring; [9][10][11][12][13] (iii) nanoinclusions, which enable acoustic phonon scatterings; 14,15 (iv) electron filtering; 16 (v) convergence of electronic band valleys; [17][18][19][20] (vi) fostering resonant levels by impurities inside the valence band; 21 (vii) alloying to create point defects; [22][23][24] (viii) complex crystal structures like skutterudites, 25,26 Zintl compounds, 27,28 hetero-structured superlattice thin-films; 29 (ix) semi-conducting glasses, [30][31][32][33][34] and (x) utilization of magnetism, [35][36][37][38] for instance.…”

Section: Introductionmentioning

confidence: 99%

Effect of the Processing Route on the Thermoelectric Performance of Nanostructured CuPb₁₈SbTe₂₀

et al. 2018

Self Cite

View full text Add to dashboard Cite

The quaternary AgPb18SbTe20 compound (abbreviated as LAST) is a prominent thermoelectric material with good performance. Endotaxially embedded nanoscale Ag-rich precipitates contribute significantly to decreased lattice thermal conductivity (latt) in LAST alloys. In this work, Ag in LAST alloys was completely replaced by the more economically available Cu. Herein, we conscientiously investigated the different routes of synthesizing CuPb18SbTe20 after vacuum-sealed tube melt processing, including: (i) slow cooling of the melt; (ii) quenching and annealing; (iii) consolidation by spark plasma sintering (SPS); and also by the state-of-the-art (iv) Flash-SPS. Irrespective of the method of synthesis, the electrical (σ) and thermal (tot) conductivities of CuPb18SbTe20 samples were akin to that of LAST alloys. Both the flash-SPSed and the slow cooled CuPb18SbTe20 samples with nanoscale dislocations and Cu-rich nanoprecipitates exhibited an ultra-low latt  0.58 W/mK at 723 K, comparable with that its Ag counterpart, regardless of differences in their size of the precipitates, type of precipitate-matrix interfaces and other nanoscopic architectures.The sample processed by flash sintering manifested higher figure of merit (zT  0.9 at 723 K), due to better optimization and trade-off between the transport properties by decreasing the carrier concentration and latt without degrading the carrier mobility. In spite of their comparable σ and tot, the zT of the Cu samples were low compared to the Ag samples due to their contrasting thermopower values. First-principles calculations attribute this variation in Seebeck to the dwindling of the energy gap (from 0.1 eV to 0.02 eV) between the valence and conduction bands in MPb18SbTe20 (M = Cu or Ag), when Cu replaces Ag. Materials and Methods ReagentsPb (Strem Chemicals, 99.999%), Sb (Alfa Aesar, 99.999%), Cu (Alfa Aesar, 99.999%) and Te (JGI, 99.999%) were used for synthesis without any further purification. SynthesisIn this work, several different processing routes were investigated, however, the first step (synthesis) was common to all of the processing routes. Samples of CuPb18SbTe20 were synthesized using the vacuumsealed tube melt processing. Stoichiometric amounts of the starting elements of Cu, Pb, Sb and Te were introduced into a fused silica tube. The tube was prepared by cleaning with hydrofluoric (HF) acid and distilled water, then dried under vacuum. The ampoules were sealed under a vacuum of 10 -6 Torr, then placed in a rocking furnace and slowly heated to 1223 K over a period of 12 hours, then held at that temperature for 15 hours. Four different batches of samples were prepared, the first two were produced directly from the molten material, followed by: (i) cooling the melt to room temperature over a period of 18 hours (samples denoted as 'SS'); (ii) rapidly quenching the tube in water, followed by annealing at 973 K for 8 hours (denoted as 'MQ'). The other two batches used the material produced by method (i), which was crushed and milled. The powders were then ...

show abstract

“…All abovementioned phenomena also revealed in Figure 4b at airflow velocity of 2.0 m/s, and the heat transfer rate of those heat exchangers in Figure 4b is increased by a factor ranging from 2.9 to 1.8 compared with the results in Figure 4a depending on the PHP condition. Equations (1) and (2) show that the heat transfer rate is in proportion to both the mass flow rate and the temperature difference between the inlet and outlet of the airflow. The higher heat transfer rate in Figure 4b was In addition, the heat transfer rate of the heat exchanger possessing a HFE-7000-charged PHP without being degassed in Figure 4a has to be mentioned in particular.…”

Section: Thermal Performance Of the Heat Exchangermentioning

confidence: 99%

“…Sources of low temperature waste heat mostly include heat loss from industrial products, equipment and processes, and heat discharged from combustion processes. Therefore, using heat exchangers to recover the low temperature waste heat would be the major approach rather than the thermoelectric units [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation on the Thermal Performance of Pulsating Heat Pipe Heat Exchangers

et al. 2020

View full text Add to dashboard Cite

In this study, the vertically-oriented pulsating heat pipe (PHP) heat exchangers charged with either water or HFE-7000 in a filling ratio of 35% or 50% were fabricated to exchange the thermal energy between two air streams in a parallel-flow arrangement. Both the effectiveness of the heat exchangers and the thermal resistance of PHP with a size of 132 × 44 × 200 mm, at a specific evaporator temperature ranging from 55 to 100 °C and a specific airflow velocity ranging from 0.5 to 2.0 m/s were estimated. The results show that the heat pipe charged with HFE-7000 in either filling ratio is likely to function as an interconnected array of thermosiphon under all tested conditions because of the unfavorable tube inner diameter, whereas the water-charged PHP possibly creates the pulsating movement of the liquid and vapor slugs once the evaporator temperature is high enough, especially in a filling ratio of 50%. The degradation in the thermal performance of the HFE-7000-charged PHP heat exchanger resulted from the non-condensable gas in the tube became diminished as the evaporator temperature was increased. By examining the effectiveness of the present heat exchangers, it is suggested that water is a suitable working fluid while employing the PHP heat exchanger at an evaporator temperature higher than 70 °C. On the other hand, HFE-7000 is applicable to the PHP used at an evaporator temperature lower than 70 °C.

show abstract

Enhancement in thermoelectric performance of n-type Pb-deficit Pb-Sb-Te alloys

Cited by 22 publications

References 38 publications

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge_1−x−yGa_xSb_yTe via band engineering and hybrid flash-SPS processing

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge_1−x−yGa_xSb_yTe via band engineering and hybrid flash-SPS processing

Effect of the Processing Route on the Thermoelectric Performance of Nanostructured CuPb₁₈SbTe₂₀

Experimental Investigation on the Thermal Performance of Pulsating Heat Pipe Heat Exchangers

Contact Info

Product

Resources

About

Enhancement in thermoelectric performance of n-type Pb-deficit Pb-Sb-Te alloys

Cited by 22 publications

References 38 publications

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge1−x−yGaxSbyTe via band engineering and hybrid flash-SPS processing

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge1−x−yGaxSbyTe via band engineering and hybrid flash-SPS processing

Effect of the Processing Route on the Thermoelectric Performance of Nanostructured CuPb18SbTe20

Experimental Investigation on the Thermal Performance of Pulsating Heat Pipe Heat Exchangers

Contact Info

Product

Resources

About

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge_1−x−yGa_xSb_yTe via band engineering and hybrid flash-SPS processing

Realizing a stable high thermoelectric zT ∼ 2 over a broad temperature range in Ge_1−x−yGa_xSb_yTe via band engineering and hybrid flash-SPS processing

Effect of the Processing Route on the Thermoelectric Performance of Nanostructured CuPb₁₈SbTe₂₀