Demonstration of ultrahigh thermoelectric efficiency of ∼7.3% in Mg3Sb2/MgAgSb module for low-temperature energy harvesting

Zihang Liu; Naoki Sato; Weihong Gao; Kunio Yubuta; Naoyuki Kawamoto; Masanori Mitome; Keiji Kurashima; Yuka Owada; Kazuo Nagase; Chul Ho Lee; Jangho Yi; Koichi Tsuchiya; Takao Mori

doi:10.1016/j.joule.2021.03.017

Demonstration of ultrahigh thermoelectric efficiency of ∼7.3% in Mg₃Sb₂/MgAgSb module for low-temperature energy harvesting

Zihang Liu, Naoki Sato, Weihong Gao, Kunio Yubuta, Naoyuki Kawamoto, Masanori Mitome, Keiji Kurashima, Yuka Owada, Kazuo Nagase, Chul Ho Lee, Jangho Yi, Koichi Tsuchiya, Takao Mori

研究成果: ジャーナルへの寄稿 › 学術誌 › 査読

116 被引用数 (Scopus)

抄録

Thermoelectric harvesting of low-temperature waste heat offers great opportunities for sustainable energy production. However, the investigations of related thermoelectric materials and modules remain sluggish. Here, we reported a great advance in the n-type Mg₃Sb_1.5Bi_0.5 system by minor Cu additions. Some Cu atoms preferentially occupy interstitial sites within the Mg₃Sb₂ lattice and significantly modified phonon modes via filling in the phonon gap and increased anharmonic phonon scattering, thereby leading to the anomalously low thermal conductivity. Simultaneously, the detrimental behavior of thermally activated electrical conductivity was completely eliminated through grain-boundary complexion engineering. These two critical roles contributed to the remarkable improvement of zT. Based on this developed high-performance material coupled with p-type α-MgAgSb-based material, a fabricated thermoelectric module rivaling long-time champion Bi₂Te₃, demonstrated a record-high conversion efficiency ∼7.3% at the hot-side temperature of 593 K. These results pave the way for low-temperature thermoelectric harvesting.

本文言語	英語
ページ（範囲）	1196-1208
ページ数	13
ジャーナル	Joule
巻	5
号	5
DOI	https://doi.org/10.1016/j.joule.2021.03.017
出版ステータス	出版済み - 5月 19 2021
外部発表	はい

!!!All Science Journal Classification (ASJC) codes

エネルギー（全般）

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10.1016/j.joule.2021.03.017

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@article{efd7eb45a65049aeb595a0961a10b830,

title = "Demonstration of ultrahigh thermoelectric efficiency of ∼7.3% in Mg3Sb2/MgAgSb module for low-temperature energy harvesting",

abstract = "Thermoelectric harvesting of low-temperature waste heat offers great opportunities for sustainable energy production. However, the investigations of related thermoelectric materials and modules remain sluggish. Here, we reported a great advance in the n-type Mg3Sb1.5Bi0.5 system by minor Cu additions. Some Cu atoms preferentially occupy interstitial sites within the Mg3Sb2 lattice and significantly modified phonon modes via filling in the phonon gap and increased anharmonic phonon scattering, thereby leading to the anomalously low thermal conductivity. Simultaneously, the detrimental behavior of thermally activated electrical conductivity was completely eliminated through grain-boundary complexion engineering. These two critical roles contributed to the remarkable improvement of zT. Based on this developed high-performance material coupled with p-type α-MgAgSb-based material, a fabricated thermoelectric module rivaling long-time champion Bi2Te3, demonstrated a record-high conversion efficiency ∼7.3% at the hot-side temperature of 593 K. These results pave the way for low-temperature thermoelectric harvesting.",

author = "Zihang Liu and Naoki Sato and Weihong Gao and Kunio Yubuta and Naoyuki Kawamoto and Masanori Mitome and Keiji Kurashima and Yuka Owada and Kazuo Nagase and Lee, {Chul Ho} and Jangho Yi and Koichi Tsuchiya and Takao Mori",

note = "Funding Information: This work was supported by JST Mirai Program grant no. JPMJMI19A1 and JSPS KAKENHI JP17H02749 , JP16H06441 . The computation in this work has been performed using Numerical Materials Simulator at NIMS. Z. Liu acknowledges the financial support from the NIMS-MANA Postdoctoral Fellowship. C.H. Lee also thanks JST CREST grant number JPMJCR20Q4 for funding. K. Yubuta thanks JSPS KAKENHI grant number JP20H05258 for funding and thanks Akira Yasuhara, JEOL, for assistance with JEM-ARM200F observations. Funding Information: This work was supported by JST Mirai Program grant no. JPMJMI19A1 and JSPS KAKENHI JP17H02749, JP16H06441. The computation in this work has been performed using Numerical Materials Simulator at NIMS. Z. Liu acknowledges the financial support from the NIMS-MANA Postdoctoral Fellowship. C.H. Lee also thanks JST CREST grant number JPMJCR20Q4 for funding. K. Yubuta thanks JSPS KAKENHI grant number JP20H05258 for funding and thanks Akira Yasuhara, JEOL, for assistance with JEM-ARM200F observations. Z.L. and T.M. developed the concept and designed the experiments. N.S. carried out the theoretical calculations. W.G. K.Y. N.K. M.M. K.K. and Y.O. performed the TEM observations and related analysis. Z.L. K.N. and C.L. made the thermoelectric module and performed the measurement. J.Y. and K.T. performed the EBSD observation and analysis. T.M. supervised the whole project. All authors discussed the results and commented on the manuscript. T.M. and Z.L. have filed two Japanese patent applications (2020?151704 and 2020?155093) on the work described here. Publisher Copyright: {\textcopyright} 2021 The Authors",

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T1 - Demonstration of ultrahigh thermoelectric efficiency of ∼7.3% in Mg3Sb2/MgAgSb module for low-temperature energy harvesting

AU - Liu, Zihang

AU - Sato, Naoki

AU - Gao, Weihong

AU - Yubuta, Kunio

AU - Kawamoto, Naoyuki

AU - Mitome, Masanori

AU - Kurashima, Keiji

AU - Owada, Yuka

AU - Nagase, Kazuo

AU - Lee, Chul Ho

AU - Yi, Jangho

AU - Tsuchiya, Koichi

AU - Mori, Takao

N1 - Funding Information: This work was supported by JST Mirai Program grant no. JPMJMI19A1 and JSPS KAKENHI JP17H02749 , JP16H06441 . The computation in this work has been performed using Numerical Materials Simulator at NIMS. Z. Liu acknowledges the financial support from the NIMS-MANA Postdoctoral Fellowship. C.H. Lee also thanks JST CREST grant number JPMJCR20Q4 for funding. K. Yubuta thanks JSPS KAKENHI grant number JP20H05258 for funding and thanks Akira Yasuhara, JEOL, for assistance with JEM-ARM200F observations. Funding Information: This work was supported by JST Mirai Program grant no. JPMJMI19A1 and JSPS KAKENHI JP17H02749, JP16H06441. The computation in this work has been performed using Numerical Materials Simulator at NIMS. Z. Liu acknowledges the financial support from the NIMS-MANA Postdoctoral Fellowship. C.H. Lee also thanks JST CREST grant number JPMJCR20Q4 for funding. K. Yubuta thanks JSPS KAKENHI grant number JP20H05258 for funding and thanks Akira Yasuhara, JEOL, for assistance with JEM-ARM200F observations. Z.L. and T.M. developed the concept and designed the experiments. N.S. carried out the theoretical calculations. W.G. K.Y. N.K. M.M. K.K. and Y.O. performed the TEM observations and related analysis. Z.L. K.N. and C.L. made the thermoelectric module and performed the measurement. J.Y. and K.T. performed the EBSD observation and analysis. T.M. supervised the whole project. All authors discussed the results and commented on the manuscript. T.M. and Z.L. have filed two Japanese patent applications (2020?151704 and 2020?155093) on the work described here. Publisher Copyright: © 2021 The Authors

PY - 2021/5/19

Y1 - 2021/5/19

N2 - Thermoelectric harvesting of low-temperature waste heat offers great opportunities for sustainable energy production. However, the investigations of related thermoelectric materials and modules remain sluggish. Here, we reported a great advance in the n-type Mg3Sb1.5Bi0.5 system by minor Cu additions. Some Cu atoms preferentially occupy interstitial sites within the Mg3Sb2 lattice and significantly modified phonon modes via filling in the phonon gap and increased anharmonic phonon scattering, thereby leading to the anomalously low thermal conductivity. Simultaneously, the detrimental behavior of thermally activated electrical conductivity was completely eliminated through grain-boundary complexion engineering. These two critical roles contributed to the remarkable improvement of zT. Based on this developed high-performance material coupled with p-type α-MgAgSb-based material, a fabricated thermoelectric module rivaling long-time champion Bi2Te3, demonstrated a record-high conversion efficiency ∼7.3% at the hot-side temperature of 593 K. These results pave the way for low-temperature thermoelectric harvesting.

AB - Thermoelectric harvesting of low-temperature waste heat offers great opportunities for sustainable energy production. However, the investigations of related thermoelectric materials and modules remain sluggish. Here, we reported a great advance in the n-type Mg3Sb1.5Bi0.5 system by minor Cu additions. Some Cu atoms preferentially occupy interstitial sites within the Mg3Sb2 lattice and significantly modified phonon modes via filling in the phonon gap and increased anharmonic phonon scattering, thereby leading to the anomalously low thermal conductivity. Simultaneously, the detrimental behavior of thermally activated electrical conductivity was completely eliminated through grain-boundary complexion engineering. These two critical roles contributed to the remarkable improvement of zT. Based on this developed high-performance material coupled with p-type α-MgAgSb-based material, a fabricated thermoelectric module rivaling long-time champion Bi2Te3, demonstrated a record-high conversion efficiency ∼7.3% at the hot-side temperature of 593 K. These results pave the way for low-temperature thermoelectric harvesting.

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