TY - JOUR
T1 - Chemical Insights into PbSe- x%HgSe
T2 - High Power Factor and Improved Thermoelectric Performance by Alloying with Discordant Atoms
AU - Hodges, James M.
AU - Hao, Shiqiang
AU - Grovogui, Jann A.
AU - Zhang, Xiaomi
AU - Bailey, Trevor P.
AU - Li, Xiang
AU - Gan, Zhehong
AU - Hu, Yan Yan
AU - Uher, Ctirad
AU - Dravid, Vinayak P.
AU - Wolverton, Chris
AU - Kanatzidis, Mercouri G.
N1 - Publisher Copyright:
© 2018 American Chemical Society.
PY - 2018/12/26
Y1 - 2018/12/26
N2 - Thermoelectric generators can convert heat directly into usable electric power but suffer from low efficiencies and high costs, which have hindered wide-scale applications. Accordingly, an important goal in the field of thermoelectricity is to develop new high performance materials that are composed of more earth-abundant elements. The best systems for midtemperature power generation rely on heavily doped PbTe, but the Te in these materials is scarce in the Earth's crust. PbSe is emerging as a less expensive alternative to PbTe, although it displays inferior performance due to a considerably smaller power factor S 2 σ, where S is the Seebeck coefficient and σ is electrical conductivity. Here, we present a new p-type PbSe system, Pb 0.98 Na 0.02 Se-x%HgSe, which yields a very high power factor of ∼20 μW·cm -1 ·K -2 at 963 K when x = 2, a 15% improvement over the best performing PbSe-x%MSe materials. The enhancement is attributed to a combination of high carrier mobility and the early onset of band convergence in the Hg-alloyed samples (∼550 K), which results in a significant increase in the Seebeck coefficient. Interestingly, we find that the Hg 2+ cations sit at an off-centered position within the PbSe lattice, and we dub the displaced Hg atoms "discordant". DFT calculations indicate that this feature plays a role in lowering thermal conductivity, and we believe that this insight may inspire new design criteria for engineering high performance thermoelectric materials. The high power factor combined with a decrease in thermal conductivity gives a high figure of merit ZT of 1.7 at 970 K, the highest value reported for p-type PbSe to date.
AB - Thermoelectric generators can convert heat directly into usable electric power but suffer from low efficiencies and high costs, which have hindered wide-scale applications. Accordingly, an important goal in the field of thermoelectricity is to develop new high performance materials that are composed of more earth-abundant elements. The best systems for midtemperature power generation rely on heavily doped PbTe, but the Te in these materials is scarce in the Earth's crust. PbSe is emerging as a less expensive alternative to PbTe, although it displays inferior performance due to a considerably smaller power factor S 2 σ, where S is the Seebeck coefficient and σ is electrical conductivity. Here, we present a new p-type PbSe system, Pb 0.98 Na 0.02 Se-x%HgSe, which yields a very high power factor of ∼20 μW·cm -1 ·K -2 at 963 K when x = 2, a 15% improvement over the best performing PbSe-x%MSe materials. The enhancement is attributed to a combination of high carrier mobility and the early onset of band convergence in the Hg-alloyed samples (∼550 K), which results in a significant increase in the Seebeck coefficient. Interestingly, we find that the Hg 2+ cations sit at an off-centered position within the PbSe lattice, and we dub the displaced Hg atoms "discordant". DFT calculations indicate that this feature plays a role in lowering thermal conductivity, and we believe that this insight may inspire new design criteria for engineering high performance thermoelectric materials. The high power factor combined with a decrease in thermal conductivity gives a high figure of merit ZT of 1.7 at 970 K, the highest value reported for p-type PbSe to date.
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U2 - 10.1021/jacs.8b11050
DO - 10.1021/jacs.8b11050
M3 - Article
C2 - 30461275
AN - SCOPUS:85058798699
SN - 0002-7863
VL - 140
SP - 18115
EP - 18123
JO - Journal of the American Chemical Society
JF - Journal of the American Chemical Society
IS - 51
ER -