Facile rapid synthesis of a nanocrystalline Cu<sub>2</sub>Te multi-phase transition material and its thermoelectric performance

Qiu, Yuchong; Ye, Jinwen; Liu, Ying; Yang, Xiaojiao

doi:10.1039/c7ra02145c

Cited by 35 publications

(22 citation statements)

References 45 publications

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“…However, at high temperature, the TE performance is greatly improved over a large temperature range, which can be traced to the suppressed phase transition temperature and the reduced carrier concentration. Specifically, the maximum zT value for pristine Cu 2 Te is only 0.4 and it is remarkably boosted to 1.8 for Cu 2 Te + 50% Ag 2 Te at 1000 K. This is a 323% improvement over Cu 2 Te itself and outperforms any other Cu 2 Te‐based material reported so far (Figure f) …”

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confidence: 71%

“…However, the case is different in Cu 2 X‐based liquid‐like TE materials that are among the hottest materials in recent TE study. They possess exceptionally low thermal conductivity and excellent zT s with the values of 1.7–1.9 for Cu 2 S, 1.5–2.3 for Cu 2 Se, and 0.4–1.1 for Cu 2 Te (see Figure ) . It is quite abnormal and interesting that the zT in Cu 2 Te is lower than those in Cu 2 S and Cu 2 Se.…”

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confidence: 95%

“…a) Electrical conductivity σ, b) Seebeck coefficient S , c) power factor PF, d) total thermal conductivity κ, and e) TE figure of merit zT . f) Comparison of zT values from 300 to 1000 K for several reported Cu 2 Te‐based TE materials …”

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confidence: 99%

“…The other symbols are the data from refs. –. The dashed lines are derived from the single parabolic band (SPB) model with the weighted mobility µ 0 m *3/2 of 19.6 m e 3/2 cm 2 V −1 s −1 .…”

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Are Cu₂Te‐Based Compounds Excellent Thermoelectric Materials?

et al. 2019

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With the increasingly serious environmental pollution and intensified energy crisis, exploitation and utilization of new kinds of clean energy resources are imperative. Among them, thermoelectric (TE) conversion technology based on highperformance TE materials enables direct energy conversion between heat and electricity through the movement of internal phonons and charge carriers. [1][2][3][4] It has shown extensive and important prospects in power generation using industrial waste heat and electronic refrigeration. [5] The energy conversion efficiency of a TE material is mainly determined by its dimensionless figure of merit, defined as zT = σS 2 T/(κ L + κ e ), where σ, S, T, κ L , and κ e are the electrical conductivity, Seebeck coefficient, absolute temperature, lattice thermal conductivity, and electronic thermal conductivity, respectively. The general criteria for high zTs require high crystal symmetry for materials, many valleys (carrier pockets) near the Fermi level, heavy elements with small electronegativity differences between the constituent elements, or complex crystal structure, etc. [6][7][8][9][10] For the constituent elements in the same group such as S, Se, and Te, the heavy one (Te and Se) always has large atomic mass for low κ L and more covalent bonding character for large carrier mobility (µ H ) and thus outstanding electrical transports. [10] Therefore, the zTs are usually high in tellurides and selenides, but they are low in sulfides. This is the general phenomenon that has been observed in those well-known TE materials such as Bi 2 X 3 -, SnX-, and PbX-based compounds (X = S, Se, and Te). As shown in Figure 1, the zT values gradually improve as the anion element change from S to Se and then to Te. However, the case is different in Cu 2 X-based liquidlike TE materials that are among the hottest materials in recent TE study. They possess exceptionally low thermal conductivity and excellent zTs with the values of 1.7-1.9 for Cu 2 S, 1.5-2.3 for Cu 2 Se, and 0.4-1.1 for Cu 2 Te (see Figure 1). [48][49][50][51][52][53][54][55][56][57][58][59][60][61][62] It is quite abnormal and interesting that the zT in Cu 2 Te is lower than those in Cu 2 S and Cu 2 Se. As we known, tellurium is less electronegative, thus the chemical bonds between Cu and Te should be less ionic as compared with those in Cu 2 S and Cu 2 Se, which is beneficial for large µ H and electrical transports. Besides, the κ L in Cu 2 Te is expected lower than or similar to those in Cu 2 S and Cu 2 Se because tellurium is much heavier than sulfur and Most of the state-of-the-art thermoelectric (TE) materials exhibit high crystal symmetry, multiple valleys near the Fermi level, heavy constituent elements with small electronegativity differences, or complex crystal structure. Typically, such general features have been well observed in those well-known TE materials such as Bi 2 X 3 -, SnX-, and PbX-based compounds (X = S, Se, and Te). The performance is usually high in the materials with heavy constituent elements such as Te and Se, bu...

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Are Cu₂Te‐Based Compounds Excellent Thermoelectric Materials?

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“…Recently, copper chalcogenides compounds Cu2X (X = S, Se, Te) have attracted lots of attention for their exceptionally low thermal conductivity and high TE performances [6,[9][10][11][12][13][14][15][16][17][18][19][20][21]. The achieved zT is as high as 1.5 in Cu2-xSe, 1.7 in Cu2-xS and 1.1 in Cu2-xTe at 1000 K, which are among the top values in bulk TE materials.…”

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confidence: 99%

Measurement of electronic structure and surface reconstruction in the superionic Cu2−xTe

et al. 2021

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Recently, layered copper chalcogenides Cu2X family (X=S, Se, Te) has attracted tremendous research interests due to their high thermoelectric (TE) performance, which is partly due to the superionic behavior of mobile Cu ions, making these compounds "phonon liquids". Here, we systematically investigate the electronic structure and its temperature evolution of the less studied single crystal Cu2-xTe by the combination of angle resolved photoemission spectroscopy (ARPES) and scanning tunneling microscope/spectroscopy (STM/STS) experiments. While the band structure of the Cu2-xTe shows agreement with the calculations, we clearly observe a 2 × 2 surface reconstruction from both our low temperature ARPES and STM/STS experiments which survives up to room temperature. Interestingly, our low temperature STM experiments further reveal multiple types of reconstruction patterns, which suggests the origin of the surface reconstruction being the distributed deficiency of liquid-like Cu ions. Our findings reveal the electronic structure and impurity level of Cu2Te, which provides knowledge about its thermoelectric properties from the electronic degree of freedom.

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Recent Advances in Liquid‐Like Thermoelectric Materials

Zhao

Qiu

Shi

et al. 2019

Adv Funct Materials

167

124

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Thermoelectric technology has attracted great attention due to its ability to recover and convert waste heat into readily available electric energy. Among the various candidate materials, liquid‐like compounds have received tremendous research interest on account of their intrinsically ultralow lattice thermal conductivity, tunable electrical properties, and high thermoelectric performance. Despite their complex phase transitions and diverse crystal structures, liquid‐like materials have two independent sublattices in common: one rigid sublattice formed by immobile ions for the free transport of electrons and one liquid‐like sublattice consisting of highly mobile ions to interrupt the thermal transports. This review first outlines the common structural features of liquid‐like thermoelectrics, along with their unusual electron and phonon transport behaviors that well satisfy the concept of “phonon‐liquid electron‐crystal.” Next, some commonly adopted strategies for further improving their thermoelectric performance are highlighted. The main progress achieved in the typical liquid‐like TE materials is then summarized, with an emphasis on their diverse crystal structures, common characteristics, and unique transport properties. The recent understandings on the stability issue of liquid‐like TE materials are also introduced. Finally, an outlook is given for the liquid‐like materials with the aim to boost further development in this exciting scientific subfield.

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Facile rapid synthesis of a nanocrystalline Cu₂Te multi-phase transition material and its thermoelectric performance

Cited by 35 publications

References 45 publications

Are Cu₂Te‐Based Compounds Excellent Thermoelectric Materials?

Are Cu₂Te‐Based Compounds Excellent Thermoelectric Materials?

Measurement of electronic structure and surface reconstruction in the superionic Cu2−xTe

Recent Advances in Liquid‐Like Thermoelectric Materials

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Facile rapid synthesis of a nanocrystalline Cu2Te multi-phase transition material and its thermoelectric performance

Cited by 35 publications

References 45 publications

Are Cu2Te‐Based Compounds Excellent Thermoelectric Materials?

Are Cu2Te‐Based Compounds Excellent Thermoelectric Materials?

Measurement of electronic structure and surface reconstruction in the superionic Cu2−xTe

Recent Advances in Liquid‐Like Thermoelectric Materials

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Product

Resources

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Facile rapid synthesis of a nanocrystalline Cu₂Te multi-phase transition material and its thermoelectric performance

Are Cu₂Te‐Based Compounds Excellent Thermoelectric Materials?

Are Cu₂Te‐Based Compounds Excellent Thermoelectric Materials?