Guodong Tang, Yuqi Liu, Xiaoyu Yang, Yongsheng Zhang, Pengfei Nan, Pan Ying, Yaru Gong, Xuemei Zhang, Binghui Ge, Nan Lin, Xuefei Miao, Kun Song, Carl-Friedrich Schön, Matteo Cagnoni, Dasol Kim, Yuan Yu, Matthias Wuttig
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引用次数: 0
摘要
设计掺杂后的电子能带结构对于提高材料的热电性能至关重要。因此,了解掺杂剂如何影响费米级附近的电子态是精确调整能带结构的先决条件。在这里,我们证明了 SnTe 中的 Sn-s 态有助于提高价带顶部的态密度。这是半满 p-p σ 键(元键)及其在价带最大值(布里渊区的 L 点)轨道相位对称性的结果。这一洞察力为识别优质掺杂剂提供了秘诀。如果两个轨道的空间重叠最大化,能量差最小化,那么掺杂剂 s-态和 Te p-态之间的重叠就会最大化。这一简单的设计规则使我们能够筛选出 Al 作为一种非常有效的掺杂剂,以提高锡碲的局部态密度。通过掺入锑来调整载流子浓度,与 AgBiTe2 合金来促进能带收敛,以及引入位错来阻碍声子传播,Sn0.8Al0.08Sb0.15Te-4%AgBiTe2 在 300 至 873 K 之间的平均 ZT 达到了创纪录的 1.15,在 300 K 时的 ZT 则高达 0.36。
Interplay between metavalent bonds and dopant orbitals enables the design of SnTe thermoelectrics
Engineering the electronic band structures upon doping is crucial to improve the thermoelectric performance of materials. Understanding how dopants influence the electronic states near the Fermi level is thus a prerequisite to precisely tune band structures. Here, we demonstrate that the Sn-s states in SnTe contribute to the density of states at the top of the valence band. This is a consequence of the half-filled p-p σ-bond (metavalent bonding) and its resulting symmetry of the orbital phases at the valence band maximum (L point of the Brillouin zone). This insight provides a recipe for identifying superior dopants. The overlap between the dopant s- and the Te p-state is maximized, if the spatial overlap of both orbitals is maximized and their energetic difference is minimized. This simple design rule has enabled us to screen out Al as a very efficient dopant to enhance the local density of states for SnTe. In conjunction with doping Sb to tune the carrier concentration and alloying with AgBiTe2 to promote band convergence, as well as introducing dislocations to impede phonon propagation, a record-high average ZT of 1.15 between 300 and 873 K and a large ZT of 0.36 at 300 K is achieved in Sn0.8Al0.08Sb0.15Te-4%AgBiTe2.
期刊介绍:
Nature Communications, an open-access journal, publishes high-quality research spanning all areas of the natural sciences. Papers featured in the journal showcase significant advances relevant to specialists in each respective field. With a 2-year impact factor of 16.6 (2022) and a median time of 8 days from submission to the first editorial decision, Nature Communications is committed to rapid dissemination of research findings. As a multidisciplinary journal, it welcomes contributions from biological, health, physical, chemical, Earth, social, mathematical, applied, and engineering sciences, aiming to highlight important breakthroughs within each domain.
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