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High Thermoelectric Performance of CaMg<sub>2</sub>Bi<sub>2</sub> Enabled by Dynamic Doping and Orbital Alignment

Muchun Guo, Wenya Zhai, Jingyu Li, Jianbo Zhu, Fengkai Guo, Zihang Liu, Ming Liu, Yuke Zhu, Xingyan Dong, Yongsheng Zhang, Qian Zhang, Wei Cai, Jiehe Sui

2022Advanced Functional Materials21 citationsDOI

Abstract

Abstract Substantial progress in improving the thermoelectric performance of CaMg 2 Bi 2 ‐based materials has been made, yet existing reports barely discuss the effect of intrinsic Bi impurity on the transport properties. In this study, the first‐principles calculation shows that the Bi‐rich environment associated with Bi impurities facilitates the reduction of cation vacancy formation energy and then increases the carrier concentration. In addition, in the samples containing Bi impurity, a dynamic doping behavior caused by the redissolving of Bi second phase into the matrix with increasing temperature is identified experimentally, which force the carrier concentration to approach the optimal carrier concentration n H,opt , leading to a more than a 5 times enhancement of the figure‐of‐merit (ZT) compared to the single‐phase CaMg 2 Bi 1.94 . Moreover, by doping Ba and Yb on the Ca Site, orbital alignment is realized and phonon scattering is also enhanced. The synergistical optimization of electrical and thermal transportation brings a peak ZT of 1.24 at 873 K and a record ZT ave of 0.86 (300–873 K) in (Ca 0.5 Yb 0.25 Ba 0.25 ) 0.995 Na 0.005 Mg 2 Bi 1.98 sample.

Topics & Concepts

Materials scienceImpurityDopingThermoelectric effectFigure of meritVacancy defectCondensed matter physicsScatteringPhase (matter)Thermoelectric materialsPhononPhonon scatteringAnalytical Chemistry (journal)OptoelectronicsOpticsThermodynamicsPhysicsChemistryQuantum mechanicsChromatographyAdvanced Thermoelectric Materials and DevicesThermal Expansion and Ionic ConductivityHeusler alloys: electronic and magnetic properties