Lattice expansion enables interstitial doping to achieve a high average ZT in n‐type PbS

Lead sulfide (PbS) presents large potential in thermoelectric application due to its earth‐abundant S element. However, its inferior average ZT (ZTave) value makes PbS less competitive with its analogs PbTe and PbSe. To promote its thermoelectric performance, this study implements strategies of continuous Se alloying and Cu interstitial doping to synergistically tune thermal and electrical transport properties in n‐type PbS. First, the lattice parameter of 5.93 Å in PbS is linearly expanded to 6.03 Å in PbS0.5Se0.5 with increasing Se alloying content. This expanded lattice in Se‐alloyed PbS not only intensifies phonon scattering but also facilitates the formation of Cu interstitials. Based on the PbS0.6Se0.4 content with the minimal lattice thermal conductivity, Cu interstitials are introduced to improve the electron density, thus boosting the peak power factor, from 3.88 μW cm−1 K−2 in PbS0.6Se0.4 to 20.58 μW cm−1 K−2 in PbS0.6Se0.4−1%Cu. Meanwhile, the lattice thermal conductivity in PbS0.6Se0.4−x%Cu (x = 0–2) is further suppressed due to the strong strain field caused by Cu interstitials. Finally, with the lowered thermal conductivity and high electrical transport properties, a peak ZT ~1.1 and ZTave ~0.82 can be achieved in PbS0.6Se0.4 − 1%Cu at 300–773K, which outperforms previously reported n‐type PbS.

[1]  Yongxin Qin,et al.  High‐Ranged ZT Value Promotes Thermoelectric Cooling and Power Generation in n‐Type PbTe , 2022, Advanced Energy Materials.

[2]  C. Uher,et al.  A comprehensive review on Bi2Te3‐based thin films: Thermoelectrics and beyond , 2022, Interdisciplinary Materials.

[3]  Yu Xiao Routes to High-Ranged Thermoelectric Performance , 2022, Materials Lab.

[4]  Zihang Liu Challenges for Thermoelectric Power Generation: From a Material Perspective , 2022, Materials Lab.

[5]  Jiaqing He,et al.  The Roles of Grain Boundaries in Thermoelectric Transports , 2022, Materials Lab.

[6]  J. Arbiol,et al.  PbS-Pb-CuxS Composites for Thermoelectric Application. , 2021, ACS applied materials & interfaces.

[7]  Jinsong Wu,et al.  Bridging the miscibility gap towards higher thermoelectric performance of PbS , 2021, Acta Materialia.

[8]  Yongxin Qin,et al.  Contrasting Cu Roles Lead to High Ranged Thermoelectric Performance of PbS , 2021, Advanced Functional Materials.

[9]  Yong-liang Yu,et al.  Entropy engineering promotes thermoelectric performance in p-type chalcogenides , 2021, Nature Communications.

[10]  S. Pennycook,et al.  High-entropy-stabilized chalcogenides with high thermoelectric performance , 2021, Science.

[11]  S. Pennycook,et al.  Coherent Sb/CuTe Core/Shell Nanostructure with Large Strain Contrast Boosting the Thermoelectric Performance of n‐Type PbTe , 2020, Advanced Functional Materials.

[12]  G. Qiao,et al.  Multiscale structure and band configuration tuning to achieve high thermoelectric properties in n-type PbS bulks , 2020 .

[13]  G. J. Snyder,et al.  Weighted Mobility , 2020, Advanced materials.

[14]  Y. Qiu,et al.  Realizing high-efficiency power generation in low-cost PbS-based thermoelectric materials , 2020 .

[15]  G. J. Snyder,et al.  Band sharpening and band alignment enable high quality factor to enhance thermoelectric performance in n-type PbS. , 2020, Journal of the American Chemical Society.

[16]  B. Ge,et al.  Cu Interstitials Enable Carriers and Dislocations for Thermoelectric Enhancements in n-PbTe0.75Se0.25 , 2020, Chem.

[17]  G. J. Snyder,et al.  Realization of higher thermoelectric performance by dynamic doping of copper in n-type PbTe , 2019, Energy & Environmental Science.

[18]  Shengqiang Bai,et al.  Thermoelectric interface materials: A perspective to the challenge of thermoelectric power generation module , 2019, Journal of Materiomics.

[19]  Haijun Wu,et al.  Synergistically optimizing interdependent thermoelectric parameters of n-type PbSe through introducing a small amount of Zn , 2019, Materials Today Physics.

[20]  R. Gu,et al.  Investigations on distinct thermoelectric transport behaviors of Cu in n-type PbS , 2019, Journal of Alloys and Compounds.

[21]  M. Kanatzidis,et al.  Enhancement of Thermoelectric Performance for n-Type PbS through Synergy of Gap State and Fermi Level Pinning. , 2019, Journal of the American Chemical Society.

[22]  G. J. Snyder,et al.  Amphoteric Indium Enables Carrier Engineering to Enhance the Power Factor and Thermoelectric Performance in n‐Type AgnPb100InnTe100+2n (LIST) , 2019, Advanced Energy Materials.

[23]  G. J. Snyder,et al.  Boosting the thermoelectric performance of PbSe through dynamic doping and hierarchical phonon scattering , 2018 .

[24]  M. Kanatzidis,et al.  Weak Electron Phonon Coupling and Deep Level Impurity for High Thermoelectric Performance Pb1−xGaxTe , 2018 .

[25]  Gang Chen,et al.  Advances in thermoelectrics , 2018 .

[26]  Haijun Wu,et al.  Remarkable Roles of Cu To Synergistically Optimize Phonon and Carrier Transport in n-Type PbTe-Cu2Te. , 2017, Journal of the American Chemical Society.

[27]  M. Kanatzidis,et al.  Subtle Roles of Sb and S in Regulating the Thermoelectric Properties of N‐Type PbTe to High Performance , 2017 .

[28]  Yue Chen,et al.  Integrating Band Structure Engineering with All‐Scale Hierarchical Structuring for High Thermoelectric Performance in PbTe System , 2017 .

[29]  Gangjian Tan,et al.  Rationally Designing High-Performance Bulk Thermoelectric Materials. , 2016, Chemical reviews.

[30]  C. Felser,et al.  The Role of Ionized Impurity Scattering on the Thermoelectric Performances of Rock Salt AgPbmSnSe2+m , 2016, 1604.03822.

[31]  M. Zebarjadi,et al.  High-performance thermoelectric nanocomposites from nanocrystal building blocks , 2016, Nature Communications.

[32]  Hui Sun,et al.  Contrasting role of antimony and bismuth dopants on the thermoelectric performance of lead selenide , 2014, Nature Communications.

[33]  M. Kanatzidis,et al.  All-scale hierarchical thermoelectrics: MgTe in PbTe facilitates valence band convergence and suppresses bipolar thermal transport for high performance , 2013 .

[34]  Timothy P. Hogan,et al.  Raising the thermoelectric performance of p-type PbS with endotaxial nanostructuring and valence-band offset engineering using CdS and ZnS. , 2012, Journal of the American Chemical Society.

[35]  Qian Zhang,et al.  Heavy doping and band engineering by potassium to improve the thermoelectric figure of merit in p-type PbTe, PbSe, and PbTe(1-y)Se(y). , 2012, Journal of the American Chemical Society.

[36]  M. Kanatzidis,et al.  Thermoelectrics with earth abundant elements: high performance p-type PbS nanostructured with SrS and CaS. , 2012, Journal of the American Chemical Society.

[37]  Yong Liu,et al.  Electrical and thermal transport properties of Pb-based chalcogenides: PbTe, PbSe, and PbS , 2012, Journal of Alloys and Compounds.