Local Structural Distortions and Reduced Thermal Conductivity in Ge-Substituted Chalcopyrite

Sahil Tippireddy; Feridoon Azough; Vikram Vikram; Animesh Bhui; Philip A Chater; Demie Kepaptsoglou; Quentin Ramasse; Robert Freer; Ricardo Grau-Crespo; Kanishka Biswas; Paz Vaqueiro; Anthony V. Powell

doi:10.1039/D2TA06443J

Local Structural Distortions and Reduced Thermal Conductivity in Ge-Substituted Chalcopyrite

Sahil Tippireddy, Feridoon Azough, Vikram Vikram, Animesh Bhui, Philip A Chater, Demie Kepaptsoglou, Quentin Ramasse, Robert Freer, Ricardo Grau-Crespo, Kanishka Biswas, Paz Vaqueiro, Anthony V. Powell

Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Chalcopyrite, CuFeS2 is considered one of the promising n-type thermoelectric materials with high natural abundancy as a mineral. In this work, a partial substitution of germanium in CuFeS2 (CuFe1-xGexS2, 0.0 ≤ x ≤ 0.10), leads to an almost six-fold enhancement of thermoelectric properties. X-ray photoelectron spectroscopy (XPS) reveals that germanium is present in two oxidation states: Ge2+ and Ge4+. The stereochemically-active 4s2 lone-pair of electrons associated with Ge2+ induces a local structural distortion. Pair-distribution function (PDF) analysis reveal that Ge2+ ions are displaced from the centre of the GeS4 tetrahedron towards a triangular face, leading to pseudo-trigonal pyramidal coordination. This distortion is accompanied by lattice softening and an increase of the strain-fluctuation scattering parameter (ΓS), leading to a decrease in thermal conductivity. Phonon calculations demonstrate that germanium substitution leads to the appearance of resonant phonon modes. These modes lie close in energy to the acoustic and low-energy optical modes of the host matrix, with which they can interact, providing an additional mechanism for reducing the thermal conductivity. The weak chemical bonding of germanium with sulphur also leads to localized electronic states near the Fermi level which results in a high density-of-states effective mass, enabling a relatively high Seebeck coefficient to be maintained, despite the reduced electrical resistivity. This combination produces an almost three-fold improvement in the power factor, which when coupled with the substantial reduction in thermal conductivity, leads to a maximum figure-of-merit, zT ~ 0.4 at 723 K for CuFe0.94Ge0.06S2.

Original language	English
Number of pages	31
Journal	Journal of Materials Chemistry A
DOIs	https://doi.org/10.1039/D2TA06443J
Publication status	Published - 26 Oct 2022

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10.1039/D2TA06443JLicence: CC BY

SuperSTEM EPSRC Advanced Electron Microscopy (AdvEM) Facility
Lazarov, V. (Principal investigator)
EPSRC
14/03/17 → 13/03/22
Project: Research project (funded) › Research

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title = "Local Structural Distortions and Reduced Thermal Conductivity in Ge-Substituted Chalcopyrite",

abstract = "Chalcopyrite, CuFeS2 is considered one of the promising n-type thermoelectric materials with high natural abundancy as a mineral. In this work, a partial substitution of germanium in CuFeS2 (CuFe1-xGexS2, 0.0 ≤ x ≤ 0.10), leads to an almost six-fold enhancement of thermoelectric properties. X-ray photoelectron spectroscopy (XPS) reveals that germanium is present in two oxidation states: Ge2+ and Ge4+. The stereochemically-active 4s2 lone-pair of electrons associated with Ge2+ induces a local structural distortion. Pair-distribution function (PDF) analysis reveal that Ge2+ ions are displaced from the centre of the GeS4 tetrahedron towards a triangular face, leading to pseudo-trigonal pyramidal coordination. This distortion is accompanied by lattice softening and an increase of the strain-fluctuation scattering parameter (ΓS), leading to a decrease in thermal conductivity. Phonon calculations demonstrate that germanium substitution leads to the appearance of resonant phonon modes. These modes lie close in energy to the acoustic and low-energy optical modes of the host matrix, with which they can interact, providing an additional mechanism for reducing the thermal conductivity. The weak chemical bonding of germanium with sulphur also leads to localized electronic states near the Fermi level which results in a high density-of-states effective mass, enabling a relatively high Seebeck coefficient to be maintained, despite the reduced electrical resistivity. This combination produces an almost three-fold improvement in the power factor, which when coupled with the substantial reduction in thermal conductivity, leads to a maximum figure-of-merit, zT ~ 0.4 at 723 K for CuFe0.94Ge0.06S2.",

author = "Sahil Tippireddy and Feridoon Azough and Vikram Vikram and Animesh Bhui and Chater, {Philip A} and Demie Kepaptsoglou and Quentin Ramasse and Robert Freer and Ricardo Grau-Crespo and Kanishka Biswas and Paz Vaqueiro and Powell, {Anthony V.}",

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T1 - Local Structural Distortions and Reduced Thermal Conductivity in Ge-Substituted Chalcopyrite

AU - Tippireddy, Sahil

AU - Azough, Feridoon

AU - Vikram, Vikram

AU - Bhui, Animesh

AU - Chater, Philip A

AU - Kepaptsoglou, Demie

AU - Ramasse, Quentin

AU - Freer, Robert

AU - Grau-Crespo, Ricardo

AU - Biswas, Kanishka

AU - Vaqueiro, Paz

AU - Powell, Anthony V.

PY - 2022/10/26

Y1 - 2022/10/26

N2 - Chalcopyrite, CuFeS2 is considered one of the promising n-type thermoelectric materials with high natural abundancy as a mineral. In this work, a partial substitution of germanium in CuFeS2 (CuFe1-xGexS2, 0.0 ≤ x ≤ 0.10), leads to an almost six-fold enhancement of thermoelectric properties. X-ray photoelectron spectroscopy (XPS) reveals that germanium is present in two oxidation states: Ge2+ and Ge4+. The stereochemically-active 4s2 lone-pair of electrons associated with Ge2+ induces a local structural distortion. Pair-distribution function (PDF) analysis reveal that Ge2+ ions are displaced from the centre of the GeS4 tetrahedron towards a triangular face, leading to pseudo-trigonal pyramidal coordination. This distortion is accompanied by lattice softening and an increase of the strain-fluctuation scattering parameter (ΓS), leading to a decrease in thermal conductivity. Phonon calculations demonstrate that germanium substitution leads to the appearance of resonant phonon modes. These modes lie close in energy to the acoustic and low-energy optical modes of the host matrix, with which they can interact, providing an additional mechanism for reducing the thermal conductivity. The weak chemical bonding of germanium with sulphur also leads to localized electronic states near the Fermi level which results in a high density-of-states effective mass, enabling a relatively high Seebeck coefficient to be maintained, despite the reduced electrical resistivity. This combination produces an almost three-fold improvement in the power factor, which when coupled with the substantial reduction in thermal conductivity, leads to a maximum figure-of-merit, zT ~ 0.4 at 723 K for CuFe0.94Ge0.06S2.

AB - Chalcopyrite, CuFeS2 is considered one of the promising n-type thermoelectric materials with high natural abundancy as a mineral. In this work, a partial substitution of germanium in CuFeS2 (CuFe1-xGexS2, 0.0 ≤ x ≤ 0.10), leads to an almost six-fold enhancement of thermoelectric properties. X-ray photoelectron spectroscopy (XPS) reveals that germanium is present in two oxidation states: Ge2+ and Ge4+. The stereochemically-active 4s2 lone-pair of electrons associated with Ge2+ induces a local structural distortion. Pair-distribution function (PDF) analysis reveal that Ge2+ ions are displaced from the centre of the GeS4 tetrahedron towards a triangular face, leading to pseudo-trigonal pyramidal coordination. This distortion is accompanied by lattice softening and an increase of the strain-fluctuation scattering parameter (ΓS), leading to a decrease in thermal conductivity. Phonon calculations demonstrate that germanium substitution leads to the appearance of resonant phonon modes. These modes lie close in energy to the acoustic and low-energy optical modes of the host matrix, with which they can interact, providing an additional mechanism for reducing the thermal conductivity. The weak chemical bonding of germanium with sulphur also leads to localized electronic states near the Fermi level which results in a high density-of-states effective mass, enabling a relatively high Seebeck coefficient to be maintained, despite the reduced electrical resistivity. This combination produces an almost three-fold improvement in the power factor, which when coupled with the substantial reduction in thermal conductivity, leads to a maximum figure-of-merit, zT ~ 0.4 at 723 K for CuFe0.94Ge0.06S2.

U2 - 10.1039/D2TA06443J

DO - 10.1039/D2TA06443J

M3 - Article

SN - 2050-7488

JO - Journal of Materials Chemistry A

JF - Journal of Materials Chemistry A

ER -

Local Structural Distortions and Reduced Thermal Conductivity in Ge-Substituted Chalcopyrite

Abstract

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