Enhanced Thermoelectric Performance and Electronic Transport Properties of Ag-Doped Cu2- xS0.5Se0.5

Xingchen Shen; Yung Hsiang Tung; Chun Chuen Yang; Allen Benton; Chenxiao Lin; Jian He

doi:10.1021/acsaem.1c03064

Enhanced Thermoelectric Performance and Electronic Transport Properties of Ag-Doped Cu_{2- x}S_0.5Se_0.5

Xingchen Shen, Yung Hsiang Tung, Chun Chuen Yang, Allen Benton, Chenxiao Lin, Jian He

Department of Physics

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

3 Scopus citations

Abstract

In addition to eco-friendliness and low raw material cost, Cu2S0.5Se0.5 exhibits promising middle-to-high-temperature thermoelectric performance by the virtue of the coexistence of liquid-like phonon transport and electron crystal-like charge transport. Toward higher thermoelectric performance, however, in-depth studies of the electrical conduction mechanism are scarce. Herein, we investigate the electrical transport mechanism and improve the thermoelectric performance of Cu2S0.5Se0.5 by introducing Cu vacancies and substituting Cu with Ag. An optimized electronic quality factor in conjunction with a reduced lattice thermal conductivity leads to a state-of-the-art figure of merit zT ∼1.23 at 773 K and an average zT ∼0.47 between 295 and 773 K in Ag0.02Cu1.955S0.5Se0.5.

Original language	English
Pages (from-to)	14400-14406
Number of pages	7
Journal	ACS Applied Energy Materials
Volume	4
Issue number	12
DOIs	https://doi.org/10.1021/acsaem.1c03064
State	Published - 27 Dec 2021

Keywords

Cu vacancies and Ag dopants
CuSSe
electronic quality factor
scattering mechanism
thermoelectric

Access to Document

10.1021/acsaem.1c03064

Cite this

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title = "Enhanced Thermoelectric Performance and Electronic Transport Properties of Ag-Doped Cu2- xS0.5Se0.5",

abstract = "In addition to eco-friendliness and low raw material cost, Cu2S0.5Se0.5 exhibits promising middle-to-high-temperature thermoelectric performance by the virtue of the coexistence of liquid-like phonon transport and electron crystal-like charge transport. Toward higher thermoelectric performance, however, in-depth studies of the electrical conduction mechanism are scarce. Herein, we investigate the electrical transport mechanism and improve the thermoelectric performance of Cu2S0.5Se0.5 by introducing Cu vacancies and substituting Cu with Ag. An optimized electronic quality factor in conjunction with a reduced lattice thermal conductivity leads to a state-of-the-art figure of merit zT ∼1.23 at 773 K and an average zT ∼0.47 between 295 and 773 K in Ag0.02Cu1.955S0.5Se0.5.",

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T1 - Enhanced Thermoelectric Performance and Electronic Transport Properties of Ag-Doped Cu2- xS0.5Se0.5

AU - Shen, Xingchen

AU - Tung, Yung Hsiang

AU - Yang, Chun Chuen

AU - Benton, Allen

AU - Lin, Chenxiao

AU - He, Jian

N1 - Publisher Copyright: ©

PY - 2021/12/27

Y1 - 2021/12/27

N2 - In addition to eco-friendliness and low raw material cost, Cu2S0.5Se0.5 exhibits promising middle-to-high-temperature thermoelectric performance by the virtue of the coexistence of liquid-like phonon transport and electron crystal-like charge transport. Toward higher thermoelectric performance, however, in-depth studies of the electrical conduction mechanism are scarce. Herein, we investigate the electrical transport mechanism and improve the thermoelectric performance of Cu2S0.5Se0.5 by introducing Cu vacancies and substituting Cu with Ag. An optimized electronic quality factor in conjunction with a reduced lattice thermal conductivity leads to a state-of-the-art figure of merit zT ∼1.23 at 773 K and an average zT ∼0.47 between 295 and 773 K in Ag0.02Cu1.955S0.5Se0.5.

AB - In addition to eco-friendliness and low raw material cost, Cu2S0.5Se0.5 exhibits promising middle-to-high-temperature thermoelectric performance by the virtue of the coexistence of liquid-like phonon transport and electron crystal-like charge transport. Toward higher thermoelectric performance, however, in-depth studies of the electrical conduction mechanism are scarce. Herein, we investigate the electrical transport mechanism and improve the thermoelectric performance of Cu2S0.5Se0.5 by introducing Cu vacancies and substituting Cu with Ag. An optimized electronic quality factor in conjunction with a reduced lattice thermal conductivity leads to a state-of-the-art figure of merit zT ∼1.23 at 773 K and an average zT ∼0.47 between 295 and 773 K in Ag0.02Cu1.955S0.5Se0.5.

KW - Cu vacancies and Ag dopants

KW - CuSSe

KW - electronic quality factor

KW - scattering mechanism

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