Concerted Rattling in CsAg5Te3 Leading to Ultralow Thermal Conductivity and High Thermoelectric Performance

Thermoelectric (TE) materials convert heat energy directly into electricity, and introducing new materials with high conversion efficiency is a great challenge because of the rare combination of interdependent electrical and thermal transport properties required to be present in a single material. T...

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Published inAngewandte Chemie International Edition Vol. 55; no. 38; pp. 11431 - 11436
Main Authors Lin, Hua, Tan, Gangjian, Shen, Jin-Ni, Hao, Shiqiang, Wu, Li-Ming, Calta, Nicholas, Malliakas, Christos, Wang, Si, Uher, Ctirad, Wolverton, Christopher, Kanatzidis, Mercouri G.
Format Journal Article
LanguageEnglish
Published Weinheim Blackwell Publishing Ltd 12.09.2016
Wiley Subscription Services, Inc
EditionInternational ed. in English
Subjects
Coefficients
concerted rattling
Conductivity
CsAg5Te3
Direct power generation
Electrical conductivity
Electrical resistivity
Electricity
Energy
Energy conversion efficiency
Energy management
Figure of merit
Heat
Heat conductivity
Heat transfer
Ions
Scattering
State of the art
Temperature
Temperature effects
Thermal conductivity
Thermoelectric materials
Transport properties
tunnel structure
ultralow thermal conductivity
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Abstract Thermoelectric (TE) materials convert heat energy directly into electricity, and introducing new materials with high conversion efficiency is a great challenge because of the rare combination of interdependent electrical and thermal transport properties required to be present in a single material. The TE efficiency is defined by the figure of merit ZT=(S2σ) T/κ, where S is the Seebeck coefficient, σ is the electrical conductivity, κ is the total thermal conductivity, and T is the absolute temperature. A new p‐type thermoelectric material, CsAg5Te3, is presented that exhibits ultralow lattice thermal conductivity (ca. 0.18 Wm−1 K−1) and a high figure of merit of about 1.5 at 727 K. The lattice thermal conductivity is the lowest among state‐of‐the‐art thermoelectrics; it is attributed to a previously unrecognized phonon scattering mechanism that involves the concerted rattling of a group of Ag ions that strongly raises the Grüneisen parameters of the material. A p‐type thermoelectric material, CsAg5Te3, is presented. It exhibits ultralow thermal conductivity (ϰtol≈0.18 Wm−1 K−1) and a high figure of merit (ZT≈1.5 at 727 K). The low thermal conductivity is attributed to a previously unrecognized phonon scattering mechanism that involves the rattling of Ag ions, strongly raising the Grüneisen parameters of the material.
AbstractList Thermoelectric (TE) materials convert heat energy directly into electricity, and introducing new materials with high conversion efficiency is a great challenge because of the rare combination of interdependent electrical and thermal transport properties required to be present in a single material. The TE efficiency is defined by the figure of merit ZT=(S2σ) T/[kappa], where S is the Seebeck coefficient, σ is the electrical conductivity, [kappa] is the total thermal conductivity, and T is the absolute temperature. A new p-type thermoelectric material, CsAg5Te3, is presented that exhibits ultralow lattice thermal conductivity (ca. 0.18Wm-1K-1) and a high figure of merit of about 1.5 at 727K. The lattice thermal conductivity is the lowest among state-of-the-art thermoelectrics; it is attributed to a previously unrecognized phonon scattering mechanism that involves the concerted rattling of a group of Ag ions that strongly raises the Gruneisen parameters of the material.
Thermoelectric (TE) materials convert heat energy directly into electricity, and introducing new materials with high conversion efficiency is a great challenge because of the rare combination of interdependent electrical and thermal transport properties required to be present in a single material. The TE efficiency is defined by the figure of merit ZT=(S2σ) T/κ, where S is the Seebeck coefficient, σ is the electrical conductivity, κ is the total thermal conductivity, and T is the absolute temperature. A new p‐type thermoelectric material, CsAg5Te3, is presented that exhibits ultralow lattice thermal conductivity (ca. 0.18 Wm−1 K−1) and a high figure of merit of about 1.5 at 727 K. The lattice thermal conductivity is the lowest among state‐of‐the‐art thermoelectrics; it is attributed to a previously unrecognized phonon scattering mechanism that involves the concerted rattling of a group of Ag ions that strongly raises the Grüneisen parameters of the material. A p‐type thermoelectric material, CsAg5Te3, is presented. It exhibits ultralow thermal conductivity (ϰtol≈0.18 Wm−1 K−1) and a high figure of merit (ZT≈1.5 at 727 K). The low thermal conductivity is attributed to a previously unrecognized phonon scattering mechanism that involves the rattling of Ag ions, strongly raising the Grüneisen parameters of the material.
Author Wolverton, Christopher
Wu, Li-Ming
Shen, Jin-Ni
Kanatzidis, Mercouri G.
Tan, Gangjian
Calta, Nicholas
Lin, Hua
Hao, Shiqiang
Wang, Si
Uher, Ctirad
Malliakas, Christos
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  email: m-kanatzidis@northwestern.edu
  organization: Department of Chemistry, Northwestern University, IL, 60208, Evanston, USA
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Snippet Thermoelectric (TE) materials convert heat energy directly into electricity, and introducing new materials with high conversion efficiency is a great challenge...
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SubjectTerms Coefficients
concerted rattling
Conductivity
CsAg5Te3
Direct power generation
Electrical conductivity
Electrical resistivity
Electricity
Energy
Energy conversion efficiency
Energy management
Figure of merit
Heat
Heat conductivity
Heat transfer
Ions
Scattering
State of the art
Temperature
Temperature effects
Thermal conductivity
Thermoelectric materials
Transport properties
tunnel structure
ultralow thermal conductivity
Title Concerted Rattling in CsAg5Te3 Leading to Ultralow Thermal Conductivity and High Thermoelectric Performance
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