Part-crystalline part-liquid state and rattling-like thermal damping in materials with chemical-bond hierarchy

Abstract: Understanding thermal and phonon transport in solids has been of great importance in many disciplines such as thermoelectric materials, which usually requires an extremely low lattice thermal conductivity (LTC). By analyzing the finite-temperature structural and vibrational characteristics of typical thermoelectric compounds such as filled skutterudites and Cu 3 SbSe 3 , we demonstrate a concept of part-crystalline part-liquid state in the compounds with chemicalbond hierarchy, in which certain constituent spe… Show more

“…These optical phonons barely contribute to the phonon transport due to their very low sound velocities. On the other hand, the scattering channel of the phonon–phonon interaction is greatly enhanced,53, 54 leading to an additional κ L reduction mechanism as reported previously 17. It is thus conclusive that the low sound velocity, together with the low frequencies of the optical phonons, are responsible for the low κ L of Ag 8 SnSe 6 .…”

“…One successful strategy for improving zT is to enhance the power factor S 2 / ρ through band engineering,2, 3, 4, 5, 6, 7 provided the carrier concentration is optimized 8. The other effective strategy is typified by minimizing the only one independent material property, the lattice thermal conductivity ( κ L ), through nanostructuring,9, 10, 11, 12, 13, 14, 15 liquid phonons,16, 17 and lattice anharmonicity 18, 19…”

Low Sound Velocity Contributing to the High Thermoelectric Performance of Ag₈SnSe₆

“…These optical phonons barely contribute to the phonon transport due to their very low sound velocities. On the other hand, the scattering channel of the phonon–phonon interaction is greatly enhanced,53, 54 leading to an additional κ L reduction mechanism as reported previously 17. It is thus conclusive that the low sound velocity, together with the low frequencies of the optical phonons, are responsible for the low κ L of Ag 8 SnSe 6 .…”

“…One successful strategy for improving zT is to enhance the power factor S 2 / ρ through band engineering,2, 3, 4, 5, 6, 7 provided the carrier concentration is optimized 8. The other effective strategy is typified by minimizing the only one independent material property, the lattice thermal conductivity ( κ L ), through nanostructuring,9, 10, 11, 12, 13, 14, 15 liquid phonons,16, 17 and lattice anharmonicity 18, 19…”

Low Sound Velocity Contributing to the High Thermoelectric Performance of Ag₈SnSe₆

“…54 Such a low optic-mode frequency was also found in the intrinsically low thermal conductivity of the Cu 3 SbSe 3 and CdSb compounds. 9,17 The TA branch exhibited normal behavior with no interactions with the optic-phonon branches, and its frequencies smoothly expanded toward the zone boundary and saturated at~20-40 cm − 1 . The acoustic and low-frequency optic-phonon branches, which were responsible for enhanced scattering and low lattice thermal conductivity, originated from the (Sb-Se) group, as indicated in Figure 8b.…”

“…16 The bond anharmonicity serves as a measure of the deviation in lattice vibrations from a perfect harmonic motion and is characterized by the effective Grüneisen parameter. Generally, structures with a chemical bond hierarchy [17][18][19][20][21] and anisotropic multicenter bonding features 9 or those that possess a lone pair of electrons [22][23][24][25][26] exhibit a stronger anharmonicity. Therefore, the investigation of the chemical bonding, crystal structures and corresponding lattice dynamics is helpful in understanding phonon transport and the design of materials with an intrinsically low lattice thermal conductivity and high thermoelectric performance.…”

Intrinsically low thermal conductivity from a quasi-one-dimensional crystal structure and enhanced electrical conductivity network via Pb doping in SbCrSe3

“…[1][2][3][4] The thermoelectric conversion efficiency of a material depends on its dimensionless figure of merit ZT, defined as ZT = α 2 σT/κ, where α, σ, κ and T are the Seebeck coefficient, electrical conductivity, thermal conductivity and absolute temperature, respectively. 5,6 A great variety of thermoelectric materials have been developed and thoroughly studied, [7][8][9] but industrial applications are still dominated by bismuth telluride (Bi 2 Te 3 )-based alloys. 10 Therefore, extensive studies have been devoted to the enhancement of their properties.…”

Thermoelectric performance enhancement in n-type Bi2(TeSe)3 alloys owing to nanoscale inhomogeneity combined with a spark plasma-textured microstructure