TY - JOUR
T1 - All Cubic-Phase δ-TAGS Thermoelectrics Over the Entire Mid-Temperature Range
AU - Ma, Baopeng
AU - Ren, Hongrui
AU - Zhang, Fudong
AU - Peng, Zhanhui
AU - He, Hailong
AU - Cui, Minchao
AU - Ge, Zhenhua
AU - Li, Bingyu
AU - Wu, Wenwen
AU - Liang, Pengfei
AU - Xiao, Yu
AU - Chao, Xiaolian
AU - Yang, Zupei
AU - Wu, Di
N1 - Publisher Copyright:
© 2023 Wiley-VCH GmbH.
PY - 2023/4/26
Y1 - 2023/4/26
N2 - GeTe-based pseudo-binary (GeTe)x(AgSbTe2)100−x (TAGS–x) is recognized as a promising p-type mid-temperature thermoelectric material with outstanding thermoelectric performance; nevertheless, its intrinsic structural transition and metastable microstructure (due to Ag/Sb/Ge localization) restrict the long-time application of TAGS-x in practical thermoelectric devices. In this work, a series of non-stoichiometric (GeTe)x(Ag1-δSb1+δTe2+δ)100−x (x = 85∼50; δ = ≈0.20–0.23), referred to as δ-TAGS-x, with all cubic phase over the entire testing temperature range (300-773 K), is synthesized. Through optimization of crystal symmetry and microstructure, a state-of-the-art ZTmax of 1.86 at 673 K and average ZTavg of 1.43 at ≈323–773 K are realized in δ-TAGS-75 (δ = 0.21), which is the highest value among all reported cubic-phase GeTe-based thermoelectric systems so far. As compared with stoichiometric TAGS-x, the remarkable thermoelectric achieved in cubic δ-TAGS-x can be attributed to the alleviation of highly (electrical and thermal) resistive grain boundary Ag8GeTe6 phase. Moreover, δ-TAGS-x exhibits much better mechanical properties than stoichiometric TAGS-x, together with the outstanding thermoelectric performance, leading to a robust single-leg thermoelectric module with ηmax of ≈10.2% and Pmax of ≈0.191 W. The finding in this work indicates the great application potential of non-stoichiometric δ-TAGS-x in the field of mid-temperature waste heat harvesting.
AB - GeTe-based pseudo-binary (GeTe)x(AgSbTe2)100−x (TAGS–x) is recognized as a promising p-type mid-temperature thermoelectric material with outstanding thermoelectric performance; nevertheless, its intrinsic structural transition and metastable microstructure (due to Ag/Sb/Ge localization) restrict the long-time application of TAGS-x in practical thermoelectric devices. In this work, a series of non-stoichiometric (GeTe)x(Ag1-δSb1+δTe2+δ)100−x (x = 85∼50; δ = ≈0.20–0.23), referred to as δ-TAGS-x, with all cubic phase over the entire testing temperature range (300-773 K), is synthesized. Through optimization of crystal symmetry and microstructure, a state-of-the-art ZTmax of 1.86 at 673 K and average ZTavg of 1.43 at ≈323–773 K are realized in δ-TAGS-75 (δ = 0.21), which is the highest value among all reported cubic-phase GeTe-based thermoelectric systems so far. As compared with stoichiometric TAGS-x, the remarkable thermoelectric achieved in cubic δ-TAGS-x can be attributed to the alleviation of highly (electrical and thermal) resistive grain boundary Ag8GeTe6 phase. Moreover, δ-TAGS-x exhibits much better mechanical properties than stoichiometric TAGS-x, together with the outstanding thermoelectric performance, leading to a robust single-leg thermoelectric module with ηmax of ≈10.2% and Pmax of ≈0.191 W. The finding in this work indicates the great application potential of non-stoichiometric δ-TAGS-x in the field of mid-temperature waste heat harvesting.
KW - cubic phase
KW - grain boundary
KW - thermoelectric devices
KW - δ-TAGS
UR - https://www.scopus.com/pages/publications/85147276275
U2 - 10.1002/smll.202206439
DO - 10.1002/smll.202206439
M3 - 文章
C2 - 36703537
AN - SCOPUS:85147276275
SN - 1613-6810
VL - 19
JO - Small
JF - Small
IS - 17
M1 - 2206439
ER -