TY - JOUR
T1 - Origin of Low Thermal Conductivity in In4Se3
AU - Supka, Andrew R.
AU - Fornari, Marco
N1 - Funding Information:
S.D.N.L. and K.T.W. thank the Institute of Advanced Manufacturing Technology for hosting and financial support within the TEAM −TECH/2016-2/14 project of the Foundation for Polish Science, entitled “New approach for the development of efficient materials for direct conversion of heat into electricity project”, co-financed by the European Union under the European Regional Development Fund. P.V. acknowledges The Leverhulme Trust for Research Project Grant (RPG-2019-288). A.R.S. and M.F. thank the Institute for Cyber-Enabled Research at Michigan State University for access to computational facilities and Giovanni Pizzi at materialscloud.org for technical support.
Publisher Copyright:
©
PY - 2020
Y1 - 2020
N2 - In4Se3 is an attractive n-type thermoelectric material for midrange waste heat recovery, owing to its low thermal conductivity (∼0.9 W·m- 1·K-1 at 300 K). Here, we explore the relationship between the elastic properties, thermal conductivity, and structure of In4Se3. The experimentally determined average sound velocity (2010 m·s-1), Young's modulus (47 GPa), and Debye temperature (198 K) of In4Se3 are rather low, indicating considerable lattice softening. This behavior, which is consistent with low thermal conductivity, can be related to the complex bonding found in this material, in which strong covalent In-In and In-Se bonds coexist with weaker electrostatic interactions. Phonon dispersion calculations show that Einstein-like modes occur at ≈30 cm-1. These Einstein-like modes can be ascribed to weakly bonded In+ cations located between strongly bonded [(In3)5+(Se2-)3]- layers. The Grüneisen parameter for the soft-bonded In+ at the frequencies of the Einstein-like modes is large, indicating a high degree of bond anharmonicity and hence increased phonon scattering. The calculated thermal conductivity and elastic properties are in good agreement with experimental results.
AB - In4Se3 is an attractive n-type thermoelectric material for midrange waste heat recovery, owing to its low thermal conductivity (∼0.9 W·m- 1·K-1 at 300 K). Here, we explore the relationship between the elastic properties, thermal conductivity, and structure of In4Se3. The experimentally determined average sound velocity (2010 m·s-1), Young's modulus (47 GPa), and Debye temperature (198 K) of In4Se3 are rather low, indicating considerable lattice softening. This behavior, which is consistent with low thermal conductivity, can be related to the complex bonding found in this material, in which strong covalent In-In and In-Se bonds coexist with weaker electrostatic interactions. Phonon dispersion calculations show that Einstein-like modes occur at ≈30 cm-1. These Einstein-like modes can be ascribed to weakly bonded In+ cations located between strongly bonded [(In3)5+(Se2-)3]- layers. The Grüneisen parameter for the soft-bonded In+ at the frequencies of the Einstein-like modes is large, indicating a high degree of bond anharmonicity and hence increased phonon scattering. The calculated thermal conductivity and elastic properties are in good agreement with experimental results.
M3 - Article
VL - 3
SP - 12549
EP - 12556
JO - ACS Applied Energy Materials
JF - ACS Applied Energy Materials
SN - 2574-0962
IS - 12
ER -