Unconventional Doping Effect Leads to Ultrahigh Average Thermoelectric Power Factor in Cu<sub>3</sub>SbSe<sub>4</sub>‐Based Composites

Huang, Yi‐Chin; Zhang, Bin; Li, Jingwei; Zhou, Zhan; Zheng, Sikang; Li, Nanhai; Wang, Guiwen; De, Zhang; Zhang, Daliang; Han, Guang; Wang, Guoyu; Han, Xiao; Lu, Xu; Zhou, Xiaoyuan

doi:10.1002/adma.202109952

Cited by 34 publications

(40 citation statements)

References 59 publications

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“…10 In the past decades, a number of methods were carried out to increase the PF and PF ave , including adjusting the carrier concentration (n) and optimization of electronic band engineering, which were mainly achieved by doping. 11−15 Recently, we found that ternary copper-based tetrahedral structure compounds are deemed to be very promising TE materials due to their make of nontoxic constituent elements (tellurium-free) and excellent performance, such as Cu 3 SbSe 4 8,13 and Cu 2 SnSe 3 16,17 to name but a few. Among them, the Cu 2 GeSe 3 compound has attracted the increasing attention of researchers in recent years.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, a larger PF ave value is more suitable for obtaining a higher output power in practical applications . In the past decades, a number of methods were carried out to increase the PF and PF ave , including adjusting the carrier concentration ( n ) and optimization of electronic band engineering, which were mainly achieved by doping. − …”

Section: Introductionmentioning

confidence: 99%

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Inducing High Power Factor in Cu₂GeSe₃-Based Bulk Materials via (Bi, Zn)-Co-doping

Rong

Chen

et al. 2023

ACS Appl. Energy Mater.

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In this work, carrier concentration optimization and effective mass increase of Cu 2 GeSe 3 , which were considered to be a synergetic effect of electrical transport properties, were achieved by the co-doping of Bi and Zn on the Cu site. This effect led to a higher Seebeck coefficient of ∼307.76 μV K −1 at 723 K for the Cu 1.988 Bi 0.01 Zn 0.002 GeSe 3 sample. This effect also resulted in a higher power factor of ∼8.66 μW cm −1 K −2 at 723 K and an average power factor of ∼6.29 μW cm −1 K −2 at the temperature range of 303− 723 K for the Cu 1.988 Bi 0.01 Zn 0.002 GeSe 3 sample, which were ∼135 and ∼196% larger than those of pristine Cu 2 GeSe 3 , respectively, and are among the highest value of the Cu 2 GeSe 3 -based sample. Benefiting from simultaneous optimization of the power factor, the maximum ZT of ∼0.75 for the Cu 1.988 Bi 0.01 Zn 0.002 GeSe 3 sample at 723 K was obtained, which is ∼288% higher than that of Cu 2 GeSe 3 .

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Inducing High Power Factor in Cu₂GeSe₃-Based Bulk Materials via (Bi, Zn)-Co-doping

Rong

Chen

et al. 2023

ACS Appl. Energy Mater.

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“…Up to now, the strategies that are used to improve the performance of thermoelectric (TE) materials fall into two categories. One is to aim to improve the power factor PF via carrier concentration optimization, − valence band convergence, , crystal structure modulation, , density of state (DOS) resonance, − and energy filtering , and the other focuses more on reducing the lattice thermal conductivity κ lat by various approaches such as alloying, , discordant atoms, , nanostructuring, − and twinning …”

Section: Introductionmentioning

confidence: 99%

Significantly Enhanced Thermoelectric Performance Achieved in CuGaTe₂ through Dual-Element Permutations at Cation Sites

Zhu

Liu

et al. 2022

ACS Appl. Mater. Interfaces

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CuGaTe2 has become a widely studied mid-temperature thermoelectric material due to the advantages of large element abundance, proper band gap, and intrinsically high Seebeck coefficient. However, the intrinsically high lattice thermal conductivity and low room-temperature electrical conductivity result in a merely moderate thermoelectric performance for pristine CuGaTe2. In this work, we found that Cu deficiency can significantly reduce the activation energy E a of Cu vacancies from ∼0.17 eV for pristine CuGaTe2 to nearly zero for Cu0.97GaTe2, thus leading to dramatic improvements in hole concentration and power factor. More remarkably, element permutations (Ag/Cu and In/Ga) at both cation sites can effectively reduce the lattice thermal conductivity at the entire testing temperatures by producing intensive atomic-scale mass and strain fluctuations. Eventually, an ultrahigh peak ZT max value of ∼1.5 at 873 K is achieved in the composition of Cu0.72Ag0.25Ga0.6In0.4Te2, while a large average ZT avg value of ∼0.7 (323–873 K) is obtained in the Cu0.67Ag0.3Ga0.6In0.4Te2 sample, both of which are significant improvements over pristine CuGaTe2.

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“…Here, σ, S , κ e , κ L , and T stand for electrical conductivity, Seebeck coefficient, electronic and lattice thermal conductivity, and the absolute temperature, respectively . The high zT performance can be obtained by either increasing the power factor (PF = σ S 2 ) or reducing thermal conductivity. , For the purpose of promoting TE performance, the electrical properties can be promoted by carrier concentration optimization and energy band engineering , while lattice thermal conductivity can be suppressed by strengthening phonon scattering through defects , and boundaries and nanostructuring. , However, due to the strong coupling between σ, S , and κ, it is difficult to optimize these parameters simultaneously to obtain high zT values.…”

Section: Introductionmentioning

confidence: 99%

Entropy Engineering in Tellurium-Free Thermoelectric Cu₈GeSe₆ with a Stable Cubic Structure

Wang

Zhou

Zheng

et al. 2022

ACS Appl. Energy Mater.

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Argyrodite-type semiconductors, as prototypes of the "phonon-liquid electron crystal" concept, have attracted intensive attention due to their intrinsically low thermal conductivity. Like other members of this family, Cu 8 GeSe 6 undergoes structural phase transition at 330 K from a low-temperature hexagonal phase to a high-temperature hexagonal phase. Here, by employing the entropy engineering strategy through S alloying on the Se site, the phase transition temperature is lowered to below room temperature, so that the stable cubic phase is maintained in the whole operating temperature region. Cubic Cu 8 GeSe 6 exhibits a favorable electronic structure, which leads to improved carrier mobility and electrical performance. In addition, benefiting from the weak chemical bonding between Cu atoms and the [GeSe 6 ] sublattice and the disordered cation occupancy, cubic Cu 8 GeSe 6 possesses an ultralow thermal conductivity, and the sample with a nominal composition of Cu 8 GeSe 4.2 S 1.8 reaches a zT value of 0.5 at 627 K. These results provide insights for suppressing phase transition in argyrodite-type thermoelectrics.

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Unconventional Doping Effect Leads to Ultrahigh Average Thermoelectric Power Factor in Cu₃SbSe₄‐Based Composites

Cited by 34 publications

References 59 publications

Inducing High Power Factor in Cu₂GeSe₃-Based Bulk Materials via (Bi, Zn)-Co-doping

Inducing High Power Factor in Cu₂GeSe₃-Based Bulk Materials via (Bi, Zn)-Co-doping

Significantly Enhanced Thermoelectric Performance Achieved in CuGaTe₂ through Dual-Element Permutations at Cation Sites

Entropy Engineering in Tellurium-Free Thermoelectric Cu₈GeSe₆ with a Stable Cubic Structure

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Unconventional Doping Effect Leads to Ultrahigh Average Thermoelectric Power Factor in Cu3SbSe4‐Based Composites

Cited by 34 publications

References 59 publications

Inducing High Power Factor in Cu2GeSe3-Based Bulk Materials via (Bi, Zn)-Co-doping

Inducing High Power Factor in Cu2GeSe3-Based Bulk Materials via (Bi, Zn)-Co-doping

Significantly Enhanced Thermoelectric Performance Achieved in CuGaTe2 through Dual-Element Permutations at Cation Sites

Entropy Engineering in Tellurium-Free Thermoelectric Cu8GeSe6 with a Stable Cubic Structure

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Unconventional Doping Effect Leads to Ultrahigh Average Thermoelectric Power Factor in Cu₃SbSe₄‐Based Composites

Inducing High Power Factor in Cu₂GeSe₃-Based Bulk Materials via (Bi, Zn)-Co-doping

Inducing High Power Factor in Cu₂GeSe₃-Based Bulk Materials via (Bi, Zn)-Co-doping

Significantly Enhanced Thermoelectric Performance Achieved in CuGaTe₂ through Dual-Element Permutations at Cation Sites

Entropy Engineering in Tellurium-Free Thermoelectric Cu₈GeSe₆ with a Stable Cubic Structure