High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu2SnSe3

Lei Hu; Yubo Luo; Yue Wen Fang; Feiyu Qin; Xun Cao; Hongyao Xie; Jiawei Liu; Jinfeng Dong; Andrea Sanson; Marco Giarola; Xianyi Tan; Yun Zheng; Ady Suwardi; Yizhong Huang; Kedar Hippalgaonkar; Jiaqing He; Wenqing Zhang; Jianwei Xu; Qingyu Yan; Mercouri G. Kanatzidis

doi:10.1002/aenm.202100661

High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu₂SnSe₃

Lei Hu
, Yubo Luo
, Yue Wen Fang
, Feiyu Qin
, Xun Cao
, Hongyao Xie
, Jiawei Liu
, Jinfeng Dong
, Andrea Sanson
, Marco Giarola
, Xianyi Tan
, Yun Zheng
, Ady Suwardi
, Yizhong Huang
, Kedar Hippalgaonkar
, Jiaqing He
, Wenqing Zhang
, Jianwei Xu
, Qingyu Yan
, Mercouri G. Kanatzidis

Nanyang Technological University
Northwestern University
Institute of Science Tokyo
University of Padua
University of Verona
Agency for Science, Technology and Research, Singapore
Southern University of Science and Technology

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

63 Scopus citations

Abstract

The presence of high crystallographic symmetry and nanoscale defects are favorable for thermoelectrics. With proper electronic structures, a highly symmetric crystal tends to possess multiple carrier channels and promote electrical conductivity without sacrificing Seebeck coefficient. In addition, nanoscale defects can effectively scatter acoustic phonons to suppress thermal conductivity. Here, it is reported that the triple doping of Cu₂SnSe₃ leads to a high ZT value of 1.6 at 823 K for Cu_1.85Ag_0.15(Sn_0.88Ga_0.1Na_0.02)Se₃, and a decent average ZT (ZT_ave) value of 0.7 is also achieved for Cu_1.85Ag_0.15(Sn_0.93Mg_0.06Na_0.01)Se₃ from 475 to 823 K. This study reveals: 1) Ag doping on Cu sites generates numerous point defects and greatly decreases lattice thermal conductivity. 2) Doping Mg or Ga converts the monoclinic Cu₂SnSe₃ into a cubic structure. This symmetry enhancing leads to an increase in the effective mass from 0.8 m_e to 2.6 m_e (m_e, free electron mass) and the power factor from 4.3 µW cm⁻¹ K⁻² for Cu₂SnSe₃ to 11.6 µW cm⁻¹ K⁻². 3) Na doping creates dense dislocation arrays and nanoprecipitates, which strengthens the phonon scattering. 4) Pair distribution function analysis shows localized symmetry breakdown in the cubic Cu_1.85Ag_0.15(Sn_0.88Ga_0.1Na_0.02)Se₃. This work provides a standpoint to design promising thermoelectric materials by synergistically manipulating crystal symmetry and nanoscale defects.

Original language	English
Article number	2100661
Journal	Advanced Energy Materials
Volume	11
Issue number	42
DOIs	https://doi.org/10.1002/aenm.202100661
State	Published - 11 Nov 2021
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

crystal symmetry
diamondoid structure
nanoscale defects
thermoelectrics

Access to Document

10.1002/aenm.202100661

Cite this

Hu, L., Luo, Y., Fang, Y. W., Qin, F., Cao, X., Xie, H., Liu, J., Dong, J., Sanson, A., Giarola, M., Tan, X., Zheng, Y., Suwardi, A., Huang, Y., Hippalgaonkar, K., He, J., Zhang, W., Xu, J., Yan, Q., & Kanatzidis, M. G. (2021). High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu₂SnSe₃. Advanced Energy Materials, 11(42), Article 2100661. https://doi.org/10.1002/aenm.202100661

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title = "High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu2SnSe3",

abstract = "The presence of high crystallographic symmetry and nanoscale defects are favorable for thermoelectrics. With proper electronic structures, a highly symmetric crystal tends to possess multiple carrier channels and promote electrical conductivity without sacrificing Seebeck coefficient. In addition, nanoscale defects can effectively scatter acoustic phonons to suppress thermal conductivity. Here, it is reported that the triple doping of Cu2SnSe3 leads to a high ZT value of 1.6 at 823 K for Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3, and a decent average ZT (ZTave) value of 0.7 is also achieved for Cu1.85Ag0.15(Sn0.93Mg0.06Na0.01)Se3 from 475 to 823 K. This study reveals: 1) Ag doping on Cu sites generates numerous point defects and greatly decreases lattice thermal conductivity. 2) Doping Mg or Ga converts the monoclinic Cu2SnSe3 into a cubic structure. This symmetry enhancing leads to an increase in the effective mass from 0.8 me to 2.6 me (me, free electron mass) and the power factor from 4.3 µW cm−1 K−2 for Cu2SnSe3 to 11.6 µW cm−1 K−2. 3) Na doping creates dense dislocation arrays and nanoprecipitates, which strengthens the phonon scattering. 4) Pair distribution function analysis shows localized symmetry breakdown in the cubic Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3. This work provides a standpoint to design promising thermoelectric materials by synergistically manipulating crystal symmetry and nanoscale defects.",

keywords = "crystal symmetry, diamondoid structure, nanoscale defects, thermoelectrics",

author = "Lei Hu and Yubo Luo and Fang, \{Yue Wen\} and Feiyu Qin and Xun Cao and Hongyao Xie and Jiawei Liu and Jinfeng Dong and Andrea Sanson and Marco Giarola and Xianyi Tan and Yun Zheng and Ady Suwardi and Yizhong Huang and Kedar Hippalgaonkar and Jiaqing He and Wenqing Zhang and Jianwei Xu and Qingyu Yan and Kanatzidis, \{Mercouri G.\}",

note = "Publisher Copyright: {\textcopyright} 2021 Wiley-VCH GmbH",

year = "2021",

month = nov,

day = "11",

doi = "10.1002/aenm.202100661",

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Hu, L, Luo, Y, Fang, YW, Qin, F, Cao, X, Xie, H, Liu, J, Dong, J, Sanson, A, Giarola, M, Tan, X, Zheng, Y, Suwardi, A, Huang, Y, Hippalgaonkar, K, He, J, Zhang, W, Xu, J, Yan, Q & Kanatzidis, MG 2021, 'High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu₂SnSe₃', Advanced Energy Materials, vol. 11, no. 42, 2100661. https://doi.org/10.1002/aenm.202100661

TY - JOUR

T1 - High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu2SnSe3

AU - Hu, Lei

AU - Luo, Yubo

AU - Fang, Yue Wen

AU - Qin, Feiyu

AU - Cao, Xun

AU - Xie, Hongyao

AU - Liu, Jiawei

AU - Dong, Jinfeng

AU - Sanson, Andrea

AU - Giarola, Marco

AU - Tan, Xianyi

AU - Zheng, Yun

AU - Suwardi, Ady

AU - Huang, Yizhong

AU - Hippalgaonkar, Kedar

AU - He, Jiaqing

AU - Zhang, Wenqing

AU - Xu, Jianwei

AU - Yan, Qingyu

AU - Kanatzidis, Mercouri G.

PY - 2021/11/11

Y1 - 2021/11/11

N2 - The presence of high crystallographic symmetry and nanoscale defects are favorable for thermoelectrics. With proper electronic structures, a highly symmetric crystal tends to possess multiple carrier channels and promote electrical conductivity without sacrificing Seebeck coefficient. In addition, nanoscale defects can effectively scatter acoustic phonons to suppress thermal conductivity. Here, it is reported that the triple doping of Cu2SnSe3 leads to a high ZT value of 1.6 at 823 K for Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3, and a decent average ZT (ZTave) value of 0.7 is also achieved for Cu1.85Ag0.15(Sn0.93Mg0.06Na0.01)Se3 from 475 to 823 K. This study reveals: 1) Ag doping on Cu sites generates numerous point defects and greatly decreases lattice thermal conductivity. 2) Doping Mg or Ga converts the monoclinic Cu2SnSe3 into a cubic structure. This symmetry enhancing leads to an increase in the effective mass from 0.8 me to 2.6 me (me, free electron mass) and the power factor from 4.3 µW cm−1 K−2 for Cu2SnSe3 to 11.6 µW cm−1 K−2. 3) Na doping creates dense dislocation arrays and nanoprecipitates, which strengthens the phonon scattering. 4) Pair distribution function analysis shows localized symmetry breakdown in the cubic Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3. This work provides a standpoint to design promising thermoelectric materials by synergistically manipulating crystal symmetry and nanoscale defects.

AB - The presence of high crystallographic symmetry and nanoscale defects are favorable for thermoelectrics. With proper electronic structures, a highly symmetric crystal tends to possess multiple carrier channels and promote electrical conductivity without sacrificing Seebeck coefficient. In addition, nanoscale defects can effectively scatter acoustic phonons to suppress thermal conductivity. Here, it is reported that the triple doping of Cu2SnSe3 leads to a high ZT value of 1.6 at 823 K for Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3, and a decent average ZT (ZTave) value of 0.7 is also achieved for Cu1.85Ag0.15(Sn0.93Mg0.06Na0.01)Se3 from 475 to 823 K. This study reveals: 1) Ag doping on Cu sites generates numerous point defects and greatly decreases lattice thermal conductivity. 2) Doping Mg or Ga converts the monoclinic Cu2SnSe3 into a cubic structure. This symmetry enhancing leads to an increase in the effective mass from 0.8 me to 2.6 me (me, free electron mass) and the power factor from 4.3 µW cm−1 K−2 for Cu2SnSe3 to 11.6 µW cm−1 K−2. 3) Na doping creates dense dislocation arrays and nanoprecipitates, which strengthens the phonon scattering. 4) Pair distribution function analysis shows localized symmetry breakdown in the cubic Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3. This work provides a standpoint to design promising thermoelectric materials by synergistically manipulating crystal symmetry and nanoscale defects.

KW - crystal symmetry

KW - diamondoid structure

KW - nanoscale defects

KW - thermoelectrics

UR - https://www.scopus.com/pages/publications/85116574615

U2 - 10.1002/aenm.202100661

DO - 10.1002/aenm.202100661

M3 - 文章

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SN - 1614-6832

VL - 11

JO - Advanced Energy Materials

JF - Advanced Energy Materials

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M1 - 2100661

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