Thermoelectric properties of Te-doped ternary CuAgSe compounds

Cu-based chalcogenides have received increasing attention as promising thermoelectric materials due to their high efficiency, tunable transport properties, high elemental abundance and low toxicity. In this review, we summarize the recent research progress on this large family compounds covering diamond-like chalcogenides and liquid-like Cu 2 X (X=S, Se, Te) binary compounds as well as their multinary derivatives. These materials have the general features of two sublattices to decouple electron and phonon transport properties. On the one hand, the complex crystal structure and the disordered or even liquid-like sublattice bring about an intrinsically low lattice thermal conductivity. On the other hand, the rigid sublattice constitutes the charge-transport network, maintaining a decent electrical performance. For specific material systems, we demonstrate their unique structural features and outline the structure-performance correlation. Various design strategies including doping, alloying, band engineering and nanostructure architecture, covering nearly all the material scale, are also presented. Finally, the potential of the application of Cu-based chalcogenides as high-performance thermoelectric materials is briefly discussed from material design to device development.

show abstract

“…By doping Te at Se site, the thermal conductivity was significantly reduced, resulting in a zT=0.7 at 450 K in CuAgSe 0. 95 Te 0.05 [66,95].…”

Section: Ternary Derivatives Of Cu 2 Xmentioning

confidence: 99%

Copper chalcogenide thermoelectric materials

et al. 2018

View full text Add to dashboard Cite

show abstract

“…The idea is to develop a material which is glassy for phonons and crystalline for charge carriers. In the context of PGEC, various research have been reported with new TE materials with high ZT , such as skutterudites, , clathrates, , and chalcopyrite. , Recently, the superionic compounds such as, Cu 2 X, , Ag 2 X, − CuAgX (where X = S, Se, Te) and CuCrSe 2 have been in the main research focus due to new concept phonon liquid electron crystal (PLEC). These superionic materials have a rigid anion sub lattice to maintain crystalline solid, while the cations have a “liquid-like” movements to scatter the heat carrying acoustic phonons, thus satisfying the PLEC concept.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of Power Factor for Inherently Poor Thermal Conductor Ag₈GeSe₆ by Replacing Ge with Sn

Acharya

Pandey

Soni

2018

ACS Appl. Energy Mater.

View full text Add to dashboard Cite

Superionic argyrodites have been identified as thermoelectric materials with inherent ultralow lattice thermal conductivity because of liquid-like behavior of cations in a relatively larger unit cell. The major drawback for these as potential thermoelectric materials is low carrier concentration and low electrical conductivity, which however can be improved by controlling the compositions while keeping the advantageous poor thermal conductivity intact. Here, we report ∼8 times enhancement of thermoelectric power factor of Ag 8 GeSe 6 by replacing Ge with metallic Sn, at high temperatures. Thus, Ag 8 SnSe 6 has been demonstrated as an efficient thermoelectric material with ZT ∼ 0.62 at 623 K, even at a very low carrier concentration (∼10 16 cm −3 ). The extremely low thermal conductivity has been explained with weakly bonded Ag ions to rigid anion sublattice and presence of low-frequency Einstein optic modes, which provide the possibility of decoupling of charge and heat transport.

show abstract

“…Values of κ lat (κ total − κ el ) for all compositions (Figure 5e) lie below 0.5 W m −1 K −1 , which is typical of disordered superionic conductors 32,71 and significantly lower compared to that for most state-of-the-art thermoelectric materials. 17,72−76 The κ lat values of 1 and 5% Cu-containing samples (∼0.3 W m −1 K −1 ) are similar to that for Ag 2 SeS 0.01 , whereas the 10% Cu sample has slightly larger κ lat (∼0.4 W m −1 K −1 ), followed by Ag 2 Se (∼0.5 W m −1 K −1 ) at room temperature.…”

Section: ■ Results and Discussionmentioning

confidence: 92%

“…The phonon glass–electron crystal (PGEC) concept , is one important strategy for developing high-performing thermoelectric materials, where the phonon glass region provides the disorder necessary to scatter phonons (i.e., low κ total ) without significantly affecting the carrier mobility in the electron crystal region (i.e., high S 2 /ρ). The most notable systems which follow the PGEC behavior are nanostructured materials consisting of nanoparticles embedded in the host matrix that effectively scatter phonons without interfering with the carrier transport, − such as in PbTe alkaline earth element; − rattling-like behavior of guest atoms in certain host electron–crystal structures with voids, such as clathrates , and filled skutterudites; , layered systems, such as layered cobaltite oxides , and layered sulfides; − and liquid-like behavior of superionic conductors, where the metal ions are mobile within a rigid Se lattice, such as Cu 2 Se, , CuAgSe/Te, − and Ag 2 Se. , …”

Section: Introductionmentioning

confidence: 99%

Temperature-Dependent Structural Variation and Cu Substitution in Thermoelectric Silver Selenide

Jood

Ohta

2020

ACS Appl. Energy Mater.

View full text Add to dashboard Cite

Ag 2 Se is a narrow band gap semiconductor with glass-like thermal conductivity which makes it attractive for room temperature thermoelectric applications. However, its structural stability is strongly affected by compositional changes, which have led to difficulty in tuning the transport properties in the past. Here, we investigated the temperature-dependent structural stability of stoichiometric Ag 2 Se and its minute anion excess counterpart, Ag 2 SeS 0.01 , from room temperature up to the transition temperature (where low-temperature orthorhombic phase changes to high-temperature cubic phase at ∼407 K). The metastable structure, which is formed to compensate for the instability of the main orthorhombic structure in Ag 2 Se, was found to exist in the entire temperature range studied. However, no metastable structure was formed in the Ag 2 SeS 0.01 sample, proving that minute anion excess is capable of stabilizing the orthorhombic structure throughout the temperature range of interest (300−400 K). The effect of Cu substitution on the thermoelectric properties of Ag 2 SeS 0.01 was also investigated, and it was found that 1% Cu substitution ((Ag 0.99 Cu 0.01 ) 2 SeS 0.01 ) enhances carrier mobility and carrier concentration, compared to that for Ag 2 SeS 0.01 and Ag 2 Se. As a result, up to 18% enhancement in S 2 /ρ (∼2.6 mW m −1 K −2 at 300 K and ∼2.8 mW m −1 K −2 at 375 K) was achieved compared to that of the non-Cu-substituted samples. The ZT (0.7 at 300 K), however, could not be improved compared to that of Ag 2 SeS 0.01 (0.8 at 300 K) but remained higher than that of Ag 2 Se (0.5 at 300 K), due to the increase in electronic contribution to thermal conductivity .

show abstract

Thermoelectric properties of Te-doped ternary CuAgSe compounds

Cited by 37 publications

References 24 publications

Copper chalcogenide thermoelectric materials

Copper chalcogenide thermoelectric materials

Enhancement of Power Factor for Inherently Poor Thermal Conductor Ag₈GeSe₆ by Replacing Ge with Sn

Temperature-Dependent Structural Variation and Cu Substitution in Thermoelectric Silver Selenide

Contact Info

Product

Resources

About

Thermoelectric properties of Te-doped ternary CuAgSe compounds

Cited by 37 publications

References 24 publications

Copper chalcogenide thermoelectric materials

Copper chalcogenide thermoelectric materials

Enhancement of Power Factor for Inherently Poor Thermal Conductor Ag8GeSe6 by Replacing Ge with Sn

Temperature-Dependent Structural Variation and Cu Substitution in Thermoelectric Silver Selenide

Contact Info

Product

Resources

About

Enhancement of Power Factor for Inherently Poor Thermal Conductor Ag₈GeSe₆ by Replacing Ge with Sn