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Journal ArticleDOI

Thermoelectric materials for space applications

Christophe Candolfi, Soufiane El Oualid, Dorra Ibrahim, Shantanu Misra, Oussama El Hamouli, Adèle Léon, Anne Dauscher, Philippe Masschelein, Philippe Gall, Patrick Gougeon, Christopher Semprimoschnig, Bertrand Lenoir 
10 Mar 2021-Ceas Space Journal (Springer Vienna)-Vol. 13, Iss: 3, pp 325-340
TL;DR: In this article, the authors review the knowledge acquired over the last years on several families of thermoelectric materials, the performances of which are close or even higher than those conventionally used in RTGs to date.
Abstract: Solid-state energy conversion through thermoelectric effects remains the technology of choice for space applications for which, their low energy conversion efficiency is largely outweighed by the reliability and technical requirements of the mission. Radioisotope thermoelectric generators (RTGs) enable the direct conversion of the heat released by nuclear fuel into the electrical power required to energize the scientific instruments. The optimization of the conversion efficiency is intimately connected to the performances of the thermoelectric materials integrated which are governed by the transport properties of these materials. Recent advances in the design of highly efficient thermoelectric materials raise interesting prospects to further enhance the performances of RTGs for future exploratory missions in the Solar system. Here, we briefly review the knowledge acquired over the last years on several families of thermoelectric materials, the performances of which are close or even higher than those conventionally used in RTGs to date. Issues that remain to be solved are further discussed.

Summary (3 min read)

Jump to: [1. Introduction][2. State-of-the-art thermoelectric materials in RTGs][3. Novel thermoelectric materials for RTGs][3.2 Skutterudites][3.3 Novel materials operating above 1000 K][3.4 Beyond thermoelectric properties] and [Conclusions]

1. Introduction

  • Both the n- and p-type legs are brazed on the metallic plates to ensure low electrical contact resistances (too high contact resistances are detrimental to high output performances of the device).
  • One of the major drawback of RTGs is their low conversion efficiency 𝜂𝑅𝑇𝐺 , which remains on the order of 6 – 10% [1,14-16], although various non-conventional designs of the thermoelectric legs or of the TEG itself have been studied.
  • In addition, achieving extremely low values of 𝜅𝑝ℎ is usually obtained in highly-disordered or amorphous compounds [1,3], the nature of which prevents high mobility of the charge carriers, necessary to maintain 𝜌 to low values, from being achieved.
  • Their main physical properties and advantages compared to other thermoelectric compounds will be discussed before highlighting the challenges that remain to be overcome.

2. State-of-the-art thermoelectric materials in RTGs

  • Historically, chalcogenide semiconductors have been the materials of choice for thermoelectric applications in power generation [1,43,44].
  • Using 241Am as the fuel source results in lower temperatures at the hot side compared to 238Pu-based sources, making the well-mastered Bi2Te3-based TE modules a viable strategy to power European deep-space probes from the mid 2020s onwards.
  • This peculiarity is important regarding their integration in RTGs.
  • As the authors will see below, the thermal stability of optimized thermoelectric materials should be also ensured to be potential candidates for integration in RTGs.

3. Novel thermoelectric materials for RTGs

  • 1 SnX (X = Se and Te) compounds for mid-temperature range Significant efforts are currently being devoted to the identification, synthesis and optimization of novel materials with superior thermoelectric properties that could replace the state-of-the-art n-type and p-type thermoelectric compounds that have been used in RTGs for decades (Fig. 5).
  • In particular, both SnSe and SnTe have been extensively investigated due to their favorable Ac electronic properties, low lattice thermal conductivity and the high number of elements that can act as effective hole-like or electron-like dopants [56,57,66-79].
  • The VBs are mainly composed of two maxima at the L and points of the Brillouin zone, giving rise to light holes (L) and heavy holes .
  • Due to this band-shape-modification effect, the thermopower values are strongly enhanced, yielding large power factors in samples with optimized composition [90,91].

3.2 Skutterudites

  • Among the novel thermoelectric materials candidates that emerge over the last two decades, skutterudites, named after the Norwegian small mining town Skutterud where a CoAs3-based mineral has been identified in 1845, are probably the closest to a qualification into an advanced RTG.
  • This interesting ability of the structure to host various elements in these cages is the key crystallographic characteristic of skutterudites, which shapes their thermal transport [29,30].
  • The presence of these guest atoms has two important consequences on the transport properties of CoSb3.
  • The charge balance achieved between the filling element R and the complexes T4X12 yields diamagnetic semiconductors in agreement with the Zintl-Klemm formalism.
  • On the space application side, n-type skutterudites remain the leading candidates for integration into RTGs and, after more than two decades of intense research endeavor, will likely integrate the 48-couple PbTe/TAGS RTGs currently powering the Mars Curiosity rover.

3.3 Novel materials operating above 1000 K

  • While many families of thermoelectric materials exhibit their maximum thermoelectr ic performances below 800 K, only few are known to be able to operate at temperatures up to 1300 K while, concomitantly, surpassing the thermoelectric properties of the traditionally- used Ac c ted m an us cr pt Si1-xGex alloys [47].
  • The complexity and diversity of their crystal structure, along with charge carrier mobilities that remains sufficient ly high, are important ingredients to design novel efficient thermoelectric materials.
  • Compared to p-type Zintl phases, only few n-type analogues have been investigated to date [143-145].
  • For each types of clusters, an optimal MEC can be predicted either from simple electron counting rules or by electronic band structure calculations [154].

3.4 Beyond thermoelectric properties

  • They should nevertheless meet several other important requirements for integration into RTGs and space qualification.
  • The diffusion of elements into the thermoelectric materials can act as dopants, potentially degrading the thermoelectr ic performances.
  • The high stress levels that can develop within each legs can result in their breakage, thereby strongly limiting the lifetime of the module.
  • While all these aspects are common to TEGs developed for terrestrial applications in power generation at high temperatures, the tolerance of the thermoelectric materials to radiations is a specific, yet critical, facet of space applications [9,174,175].
  • While the dose received from external sources is strongly mission dependent, the interna l bombardment can be estimated.

Conclusions

  • The authors have surveyed several families of materials that exhibit transport properties relevant for thermoelectric applications in power generation, making them prime candidates for being integrated in the next generation of RTGs.
  • A central aspect of these materials is their high 𝑍𝑇 values that can be optimized through proper doping strategies.
  • The wide interest in these materials is testified by the significant, ever-growing amount of literature data available for these families.
  • While significant advances have been achieved on the material side, several issues regarding their integration in RTGs remain to be solved, notably regarding their thermal stability over long Further investigations on these materials and on other related families might uncover novel, highly-efficient thermoelectric materials that will enable further enhancing the output performances of RTGs.
  • The successful integration of these materials into RTGs may be also beneficial for the development of TEGs and their more widespread use in terrestrial applications, thereby contributing to mitigate mankind’s fingerprint on the global climate.

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HAL Id: hal-03190535
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Submitted on 18 May 2021
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Thermoelectric materials for space applications
Christophe Candol, Souane El Oualid, Dorra Ibrahim, Shantanu Misra,
Oussama El Hamouli, Adèle Léon, Anne Dauscher, Philippe Masschelein,
Philippe Gall, Patrick Gougeon, et al.
To cite this version:
Christophe Candol, Souane El Oualid, Dorra Ibrahim, Shantanu Misra, Oussama El Hamouli, et
al.. Thermoelectric materials for space applications. CEAS Space Journal, Springer, 2021, 13 (3),
pp.325-340. �10.1007/s12567-021-00351-x�. �hal-03190535�
1
Thermoelectric materials for space applications
Christophe Candolfi
1,*
, Soufiane El Oualid
1
, Dorra Ibrahim
1
, Shantanu Misra
1
, Oussama El
Hamouli
1
, Adèle Léon
1
, Anne Dauscher
1
, Philippe Masschelein
1
, Philippe Gall
2
, Patrick
Gougeon
2
, Christopher Semprimoschnig
3,†
, Bertrand Lenoir
1,*
1
Institut Jean Lamour, UMR 7198 CNRS Université de Lorraine, Campus ARTEM, 2 allée
André Guinier, BP 50840, 54011 Nancy, France
2
Institut des Sciences Chimiques de Rennes, UMR 6226 CNRS Université de Rennes 1
INSA de Rennes Ecole Nationale Supérieure de Chimie de Rennes, 11 allée de Beaulieu, CS
50837, 35708 Rennes Cedex, France
3
European Space Agency, ESTEC, P.O. Box 299, Keplerlaan 1, 2200 AG Noordwijk, The
Netherlands
*
Corresponding Authors: christophe.candolfi@univ-lorraine.fr; bertrand.lenoir@uni v-
lorraine.fr
C. S. passed away in 2020
Abstract
Solid-state energy conversion through thermoelectric effects remains the technology of choice
for space applications for which, their low energy conversion efficiency is largely outweighed
by the reliability and technical requirements of the mission. Radioisotope thermoelectric
generators (RTGs) enables the direct conversion of the heat released by nuclear fuel into the
electrical power required to energize the scientific instruments. The optimization of the
conversion efficiency is intimately connected to the performances of the thermoelectric
Accepted manuscript
2
materials integrated which are governed by the transport properties of these materials. Recent
advances in the design of highly-efficient thermoelectric materials raise interesting prospects
to further enhance the performances of RTGs for future exploratory missions in the Solar
system. Here, we briefly review the knowledge acquired over the last years on several families
of thermoelectric materials, the performances of which are close or even higher than those
conventionally used in RTGs to date. Issues that remain to be solved are further discussed.
Keywords: Thermoelectric, RTG, Semiconductors, Space mission
Declarations
Funding
European Space Agency (ESA/ESTEC)
Conflicts of Interest
The authors declare no competing financial interest.
Availability of data and material
Not applicable
Code availability
Not applicable
Accepted manuscript
3
1. Introduction
Thermoelectric materials provide an elegant and versatile way to convert a temperature
difference into electrical power (Seebeck effect) or vice versa (Peltier effect) [1-3].
Thermoelectric generators (TEGs, see Fig. 1), in which these materials are integrated, possess
important advantages over other energy conversion technologies. In particular, the TEGs does
not exhibit any moving parts and are thus noise- and vibration-free during operation, conferring
high mechanical reliability with low maintenance levels and hence, long lifetime. These
properties make TEGs fully autonomous and particularly well-suited for operating in isolated
areas on Earth and in the extreme environments of space and other planetary surfaces. These
TEGs can be either scaled up or downsized, offering a high adaptability for a plethora of
applications ranging from waste-heat recovery in various industrial processes to the powering
of autonomous micro-sensors for Internet-of-things (IoT) applications [4-8].
Accepted manuscript
4
N
P
Ceramicplates
Metallicplates
a)
N
P
Diffusionbarrier
Braze
b)
P
1
P
2
P
1
P
2
N
1
N
2
Ceramicplates
M etallicplates
c)
P
1
P
2
N
1
N
2
Diffusionbarriers
Braze
Braze
Diffusionbarriers
d)
Accepted manuscript
Citations
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Abstract: The anharmonic lattice dynamics of rock-salt thermoelectric compounds SnTe and PbTe are investigated with inelastic neutron scattering (INS) and first-principles calculations. The experiments show that, surprisingly, although SnTe is closer to the ferroelectric instability, phonon spectra in PbTe exhibit a more anharmonic character. This behavior is reproduced in first-principles calculations of the temperature-dependent phonon self-energy. Our simulations reveal how the nesting of phonon dispersions induces prominent features in the self-energy, which account for the measured INS spectra and their temperature dependence. We establish that the phase space for three-phonon scattering processes, combined with the proximity to the lattice instability, is the mechanism determining the complex spectrum of the transverse-optic ferroelectric mode.

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Guilin University of Electronic Technology1, Sun Yat-sen University2, Nagoya University3, Toyota Technological Institute4, Shibaura Institute of Technology5
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Abstract: As the first-generation semiconductor, silicon (Si) exhibits promising prospects in thermoelectric (TE) convention application with the advantages of un-toxic, abundant, robust, and compliant to the integrated circuit. However, Si-based TE materials are always implemented for high-temperature application and deficient at room temperature (RT) ambience. This study displays an N-type Si1−x−yGexSny thin film by carrying out the strategy of metallic modulation doping for enhancing its power factor (PF). It was distinct to observe the extra carriers poured from the precipitated Sn particles without prominent degradation of mobility while sustaining appreciable thermal conductivity. The PF of 12.21 μW cm−1 K−2 and zT of 0.27 were achieved at 125 °C, which illustrated the significant potential for implementation at near RT ambiance.

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[...]

Bo Zhang1, Jia Sun1, Howard E. Katz1, Fang Fang1, Robert L. Opila1 
Johns Hopkins University1
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Aarhus University1, Technical University of Denmark2
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TL;DR: This work reports a low-cost n-type material, Te-doped Mg3Sb1.5Bi0.5, that exhibits a very high figure of merit zT ranging from 0.56 to 1.65 at 300−725 K and shows that the high thermoelectric performance originates from the significantly enhanced power factor because of the multi-valley band behaviour dominated by a unique near-edge conduction band with a sixfold valley degeneracy
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406 citations

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Anomalous barium filling fraction and n-type thermoelectric performance of BayCo4Sb12

[...]

Linghan Chen1, T. Kawahara1, Xinfeng Tang1, Takashi Goto, Toshio Hirai1, Jeffrey S. Dyck2, Wei Chen2, Ctirad Uher2 
Tohoku University1, University of Michigan2
02 Aug 2001-Journal of Applied Physics
TL;DR: In this article, the lattice parameters increase linearly with Ba content, and the electrical conductivity increases with increasing the Ba filling fraction, reaching a maximum value of 1.1 for Ba0.24Co4Sb12 at 850 K.
Abstract: Barium-filled skutterudites BayCo4Sb12 with an anomalously large filling fraction of up to y=0.44 have been synthesized. The lattice parameters increase linearly with Ba content. Magnetic susceptibility data show that Ba0.44Co4Sb12 is paramagnetic, which implies that some of the Co atoms in BayCo4Sb12 have acquired a magnetic moment. The presence of the two different valence states of Co (Co3+ and Co2+) leads to the anomalously large barium filling fraction even without extra charge compensation. All samples show n-type conduction. The electrical conductivity increases with increasing the Ba filling fraction. The lattice thermal conductivity of BayCo4Sb12 is significantly depressed as compared to unfilled Co4Sb12. The dimensionless thermoelectric figure of merit, ZT, increases with increasing temperature reaching a maximum value of 1.1 for Ba0.24Co4Sb12 at 850 K.

393 citations

Journal ArticleDOI
High thermoelectric cooling performance of n-type Mg 3 Bi 2 -based materials.

[...]

Jun Mao1, Hangtian Zhu1, Zhiwei Ding2, Zihang Liu1, Geethal Amila Gamage1, Gang Chen2, Zhifeng Ren1 
Texas Center for Superconductivity1, Massachusetts Institute of Technology2
02 Aug 2019-Science
TL;DR: In this article, the authors reported n-type magnesium bismuthide (Mg3Bi2)-based materials with a peak figure of merit (ZT) of 0.9 at 350 kelvin.
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381 citations

Journal ArticleDOI
High-Temperature Thermoelectric Properties of NaxCoO2-δ Single Crystals

[...]

Kenjiro Fujita1, Tadashi Mochida1, Kazuo Nakamura1
Tokyo Gas1
01 Jul 2001-Japanese Journal of Applied Physics
TL;DR: In this article, the authors measured the high-temperature thermoelectric properties of the NaxCoO2-? single crystal for the first time and showed that the in-plane electrical resistivity (?), the inplane thermal conductivity (S), and the in plane thermal power (S) of the single crystal can be measured in the range of 300 K to 800 K. The single crystal is prepared by a flux technique, and the resulting flaky single crystals are very thin on the c-axis.
Abstract: We measure the high-temperature thermoelectric properties of the NaxCoO2-? single crystal for the first time. The NaxCoO2-? single crystals are prepared by a flux technique, and the resulting flaky single crystals are very thin on the c-axis. The in-plane electrical resistivity (?), the thermoelectric power (S) and the in-plane thermal conductivity (?) are measured in the range of 300 K to 800 K. The estimated power factor (PF=S2??-1) and the figure-of-merit (Z=S2??-1?-1) are about 2.4 mW m-1 K-2 and 0.12 mK-1 at 300 K, respectively. These factors increase with temperature, and reach the value of PF=7.7 mW m-1 K-2 and Z=1.5 mK-1 at 800 K, and the dimensionless value of ZT exceeds the criterion of 1. The PF and Z exceed the values of typical ?high-temperature thermoelectric materials?, such as p-type FeSi2 and Si0.7Ge0.3. These results suggest that NaxCoO2-? could be a very promising material for use in high-temperature thermoelectric power generation devices.

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Frequently Asked Questions (1)
Q1. What contributions have the authors mentioned in the paper "Thermoelectric materials for space applications" ?

In this paper, a thermoelectric generator with segmented legs is presented, where the n-and p-type legs are brazed on the metallic plates to ensure low electrical contact resistances.