A comprehensive study on improved power materials for high-temperature thermoelectric generators

Bittner, Michael; Kanas, Nikola; Hinterding, Richard; Steinbach, Frank; Räthel, Jan; Schrade, Matthias; Wiik, Kjell; Einarsrud, Mari‐Ann; Feldhoff, Armin

doi:10.1016/j.jpowsour.2018.10.076

Cited by 44 publications

(39 citation statements)

References 57 publications

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“…In contrast, the power factor

is proportional to the maximum achievable power output of a material and the temperature difference

T [ 20 ]:

…”

Section: Introductionmentioning

confidence: 99%

“…In this review, we take a closer look at these promising materials for high-temperature applications (>700 K), e.g., power plants, industrial processes, and the automobile industry [ 20 , 42 ]. Therefore, oxide-based materials and several intermetallic compounds such as Zintl phases and half-Heusler compounds will be discussed and compared in terms of the power factor and the figure of merit zT .…”

Section: Introductionmentioning

confidence: 99%

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High Power Factor vs. High zT—A Review of Thermoelectric Materials for High-Temperature Application

Wolf

Hinterding

Feldhoff

2019

Entropy

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134

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Energy harvesting with thermoelectric materials has been investigated with increasing attention over recent decades. However, the vast number of various material classes makes it difficult to maintain an overview of the best candidates. Thus, we revitalize Ioffe plots as a useful tool for making the thermoelectric properties of a material obvious and easily comparable. These plots enable us to consider not only the efficiency of the material by the figure of merit zT but also the power factor and entropy conductivity as separate parameters. This is especially important for high-temperature applications, where a critical look at the impact of the power factor and thermal conductivity is mandatory. Thus, this review focuses on material classes for high-temperature applications and emphasizes the best candidates within the material classes of oxides, oxyselenides, Zintl phases, half-Heusler compounds, and SiGe alloys. An overall comparison between these material classes with respect to either a high efficiency or a high power output is discussed.

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“…In contrast, the power factor

is proportional to the maximum achievable power output of a material and the temperature difference

T [ 20 ]:

…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High Power Factor vs. High zT—A Review of Thermoelectric Materials for High-Temperature Application

Wolf

Hinterding

Feldhoff

2019

Entropy

Self Cite

134

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“…With the discovery of attractive TE properties in Na x CoO 2 ceramics in 1997 [15], a lot of effort has been put in the research and development of CoO-based materials, as well as other transition metal oxides [16], which have important 'default' advantages (abundance, low-cost, environmental 'friendliness', low reactivity and high thermochemical stability) over established TE materials, enabling them to be considered for power generation applications at high temperatures and in oxidizing conditions [17][18][19][20][21]. While the best performing n-type TE oxides were found in the family of perovskite-type titanates [22][23][24][25], manganites [26][27][28][29] and ZnO-based materials [30][31][32], one of the most promising p-type TE materials (considered as the best choice for a p-type leg in a high-temperature TE module) continues to be the so-called Ca 3 Co 4 O 9 compound, belonging to the family of misfit-layered cobaltites [26].…”

Section: Introductionmentioning

confidence: 99%

Redox-Promoted Tailoring of the High-Temperature Electrical Performance in Ca3Co4O9 Thermoelectric Materials by Metallic Cobalt Addition

et al. 2020

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This paper reports a novel composite-based processing route for improving the electrical performance of Ca3Co4O9 thermoelectric (TE) ceramics. The approach involves the addition of metallic Co, acting as a pore filler on oxidation, and considers two simple sintering schemes. The (1-x)Ca3Co4O9/xCo composites (x = 0%, 3%, 6% and 9% vol.) have been prepared through a modified Pechini method, followed by one- and two-stage sintering, to produce low-density (one-stage, 1ST) and high-density (two-stage, 2ST) ceramic samples. Their high-temperature TE properties, namely the electrical conductivity (σ), Seebeck coefficient (α) and power factor (PF), were investigated between 475 and 975 K, in air flow, and related to their respective phase composition, morphology and microstructure. For the 1ST case, the porous samples (56%–61% of ρth) reached maximum PF values of around 210 and 140 μWm−1·K−2 for the 3% and 6% vol. Co-added samples, respectively, being around two and 1.3 times higher than those of the pure Ca3Co4O9 matrix. Although 2ST sintering resulted in rather dense samples (80% of ρth), the efficiency of the proposed approach, in this case, was limited by the complex phase composition of the corresponding ceramics, impeding the electronic transport and resulting in an electrical performance below that measured for the Ca3Co4O9 matrix (224 μWm−1·K−2 at 975K).

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“…A high power factor of above 7 lW/cm K 2 is reported at 900°C for In 1.9 Sn 0.05 Al 0.05 O 3 (air), also representing a promising n-type TE material. 9 Pure SrTiO 3 is a dielectric material due to a large band gap (3.2 eV), 10 but the material demonstrates high n-type electrical conductivity at reducing conditions due to the introduction of oxygen vacancies and delocalized electrons caused by Ti 3+ formation.…”

Section: Introductionmentioning

confidence: 99%

Performance of a Thermoelectric Module Based on n-Type (La0.12Sr0.88)0.95TiO3−δ and p-Type Ca3Co4−xO9+δ

Kanas

Skomedal

Desissa

et al. 2020

Journal of Elec Materi

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Here, we present the performance of a thermoelectric (TE) module consisting of n-type (La 0.12 Sr 0.88 ) 0.95 TiO 3 and p-type Ca 3 Co 4Àx O 9+d materials. The main challenge in this investigation was operating the TE module in different atmospheric conditions, since n-type has optimum TE performance at reducing conditions, while p-type has optimum at oxidizing conditions. The TE module was exposed to two different atmospheres and demonstrated higher stability in N 2 atmosphere than in air. The maximum electrical power output decreased after 40 h when the hot side was exposed to N 2 at 600°C, while only 1 h at 400°C in ambient air was enough to oxidize (La 0.12 Sr 0.88 ) 0.95 TiO 3 followed by a reduced electrical power output. The module generated maximum electrical power of 0.9 mW ($ 4.7 mW/cm 2 ) at 600°C hot side and DT $ 570 K in N 2 , and 0.15 mW ($ 0.8 mW/cm 2 ) at 400°C hot side and DT $ 370 K in air. A stability limit of Ca 3 Co 3.93 O 9+d at $ 700°C in N 2 was determined by in situ high-temperature x-ray diffraction.

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A comprehensive study on improved power materials for high-temperature thermoelectric generators

Cited by 44 publications

References 57 publications

High Power Factor vs. High zT—A Review of Thermoelectric Materials for High-Temperature Application

High Power Factor vs. High zT—A Review of Thermoelectric Materials for High-Temperature Application

Redox-Promoted Tailoring of the High-Temperature Electrical Performance in Ca3Co4O9 Thermoelectric Materials by Metallic Cobalt Addition

Performance of a Thermoelectric Module Based on n-Type (La0.12Sr0.88)0.95TiO3−δ and p-Type Ca3Co4−xO9+δ

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