High-entropy-driven half-Heusler alloys boost thermoelectric performance

Subrata Ghosh; Amin Nozariasbmarz; Huiju Lee; Lavanya Raman; Shweta Sharma; Rabeya B. Smriti; Dipika Mandal; Yu Zhang; Sumanta K. Karan; Na Liu; Jennifer L. Gray; Mohan Sanghadasa; Yi Xia; Shashank Priya; Wenjie Li; Bed Poudel

doi:10.1016/j.joule.2024.08.008

High-entropy-driven half-Heusler alloys boost thermoelectric performance

Subrata Ghosh, Amin Nozariasbmarz, Huiju Lee, Lavanya Raman, Shweta Sharma, Rabeya B. Smriti, Dipika Mandal, Yu Zhang, Sumanta K. Karan, Na Liu, Jennifer L. Gray, Mohan Sanghadasa, Yi Xia, Shashank Priya, Wenjie Li, Bed Poudel

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

15 Scopus citations

Abstract

High-entropy engineering effectively reduces lattice thermal conductivity (κ_L) in thermoelectric (TE) materials; however, the chemical complexity of multiple elements in high-entropy materials often leads to phase segregation, limiting their electrical transport properties and overall TE performance. Herein, we report a p-type high-entropy stabilized single-phase half-Heusler alloy, MFeSb, specifically designed to enhance configurational entropy by introducing multiple element species on a single atomic site. This material exhibited low κ_L due to phonon group velocity reduction and strong phonon scattering from lattice strain generated through distorted lattices while maintaining a high power factor. The material demonstrated a record high figure of merit (zT) of 1.5 at 1,060 K, with an average zT of ∼0.92 over 300–1,060 K. Furthermore, superior conversion efficiencies of 15% and 14% for a single-leg and a unicouple module at a temperature difference of ΔT ∼671 K were achieved. Our findings provide a new avenue for enhancing TE material performance through high-entropy engineering.

Original language	English (US)
Pages (from-to)	3303-3312
Number of pages	10
Journal	Joule
Volume	8
Issue number	12
DOIs	https://doi.org/10.1016/j.joule.2024.08.008
State	Published - Dec 18 2024
Externally published	Yes

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Publisher Copyright:
© 2024 Elsevier Inc.

Keywords

figure of merit
half-Heusler
hardness
high-entropy engineering
point defects
thermoelectric conversion efficiency
thermoelectric effect

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10.1016/j.joule.2024.08.008

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title = "High-entropy-driven half-Heusler alloys boost thermoelectric performance",

abstract = "High-entropy engineering effectively reduces lattice thermal conductivity (κL) in thermoelectric (TE) materials; however, the chemical complexity of multiple elements in high-entropy materials often leads to phase segregation, limiting their electrical transport properties and overall TE performance. Herein, we report a p-type high-entropy stabilized single-phase half-Heusler alloy, MFeSb, specifically designed to enhance configurational entropy by introducing multiple element species on a single atomic site. This material exhibited low κL due to phonon group velocity reduction and strong phonon scattering from lattice strain generated through distorted lattices while maintaining a high power factor. The material demonstrated a record high figure of merit (zT) of 1.5 at 1,060 K, with an average zT of ∼0.92 over 300–1,060 K. Furthermore, superior conversion efficiencies of 15% and 14% for a single-leg and a unicouple module at a temperature difference of ΔT ∼671 K were achieved. Our findings provide a new avenue for enhancing TE material performance through high-entropy engineering.",

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author = "Subrata Ghosh and Amin Nozariasbmarz and Huiju Lee and Lavanya Raman and Shweta Sharma and Smriti, {Rabeya B.} and Dipika Mandal and Yu Zhang and Karan, {Sumanta K.} and Na Liu and Gray, {Jennifer L.} and Mohan Sanghadasa and Yi Xia and Shashank Priya and Wenjie Li and Bed Poudel",

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T1 - High-entropy-driven half-Heusler alloys boost thermoelectric performance

AU - Ghosh, Subrata

AU - Nozariasbmarz, Amin

AU - Lee, Huiju

AU - Raman, Lavanya

AU - Sharma, Shweta

AU - Smriti, Rabeya B.

AU - Mandal, Dipika

AU - Zhang, Yu

AU - Karan, Sumanta K.

AU - Liu, Na

AU - Gray, Jennifer L.

AU - Sanghadasa, Mohan

AU - Xia, Yi

AU - Priya, Shashank

AU - Li, Wenjie

AU - Poudel, Bed

PY - 2024/12/18

Y1 - 2024/12/18

N2 - High-entropy engineering effectively reduces lattice thermal conductivity (κL) in thermoelectric (TE) materials; however, the chemical complexity of multiple elements in high-entropy materials often leads to phase segregation, limiting their electrical transport properties and overall TE performance. Herein, we report a p-type high-entropy stabilized single-phase half-Heusler alloy, MFeSb, specifically designed to enhance configurational entropy by introducing multiple element species on a single atomic site. This material exhibited low κL due to phonon group velocity reduction and strong phonon scattering from lattice strain generated through distorted lattices while maintaining a high power factor. The material demonstrated a record high figure of merit (zT) of 1.5 at 1,060 K, with an average zT of ∼0.92 over 300–1,060 K. Furthermore, superior conversion efficiencies of 15% and 14% for a single-leg and a unicouple module at a temperature difference of ΔT ∼671 K were achieved. Our findings provide a new avenue for enhancing TE material performance through high-entropy engineering.

AB - High-entropy engineering effectively reduces lattice thermal conductivity (κL) in thermoelectric (TE) materials; however, the chemical complexity of multiple elements in high-entropy materials often leads to phase segregation, limiting their electrical transport properties and overall TE performance. Herein, we report a p-type high-entropy stabilized single-phase half-Heusler alloy, MFeSb, specifically designed to enhance configurational entropy by introducing multiple element species on a single atomic site. This material exhibited low κL due to phonon group velocity reduction and strong phonon scattering from lattice strain generated through distorted lattices while maintaining a high power factor. The material demonstrated a record high figure of merit (zT) of 1.5 at 1,060 K, with an average zT of ∼0.92 over 300–1,060 K. Furthermore, superior conversion efficiencies of 15% and 14% for a single-leg and a unicouple module at a temperature difference of ΔT ∼671 K were achieved. Our findings provide a new avenue for enhancing TE material performance through high-entropy engineering.

KW - figure of merit

KW - half-Heusler

KW - hardness

KW - high-entropy engineering

KW - point defects

KW - thermoelectric conversion efficiency

KW - thermoelectric effect

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ER -

High-entropy-driven half-Heusler alloys boost thermoelectric performance

Abstract

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