YbZn11-xAlx† 的热电特性

IF 5.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Materials Advances Pub Date : 2024-09-09 DOI:10.1039/D4MA00626G

Shuai Li, Ruhul Quddus, Sree Sourav Das, Haobo Wang, Jerrold A. Floro and Mona Zebarjadi

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引用次数: 0

摘要

具有高热电功率因数和高热导率的金属热电材料有利于微电子的瞬态动态主动热管理。在这些材料中，有几种镱金属间化合物由于镱 f 轨道的贡献而在其状态密度中显示出尖锐的峰值。YbZn11 是这些化合物中的一种，其状态密度接近费米级，呈高斯状，是实现高热电功率因数的有利形状。如果费米级可以调整，那么根据维德曼-弗兰茨定律，就有望获得较高的塞贝克系数。在此，我们介绍了很少制作和研究的样品 YbZn11，并首次报告了其热电和传输特性。带状结构计算证实了状态密度的高斯函数形状。然而，塞贝克计算显示费米级的位置并不理想，理想情况下应偏移 200 meV。用铝代替锌（YbZn11-xAlx）和缺锌（YbZn11-x）可以改变带状结构，移动费米级以调整塞贝克系数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Thermoelectric properties of YbZn11−xAlx†

Metallic thermoelectric materials with a high thermoelectric power factor and high thermal conductivity are favorable for transient dynamic active thermal management of microelectronics. Among these, several ytterbium intermetallic compounds demonstrate sharp peaks in their density of states due to contributions from ytterbium f-orbitals. YbZn₁₁ is one of these compounds with a Gaussian-like density of states close to its Fermi level, an advantageous shape to achieve a high thermoelectric power factor. If the Fermi-level can be adjusted, high Seebeck coefficient values are expected following the Wiedemann–Franz law. Here we present YbZn₁₁, a rarely made and studied sample, and for the first time, we report its thermoelectric and transport properties. Band structure calculations confirm the Gaussian function shape of the density of states. However, Seebeck calculations show that the Fermi level is not well positioned and ideally should be shifted by 200 meV. Al substitution for Zn (YbZn_11−xAl_x) and Zn-deficiency (YbZn_11−x) are applied to modify the band structure and to shift the Fermi level to adjust the Seebeck coefficient.

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