塞贝克系数
声子
凝聚态物理
热电效应
有效质量(弹簧-质量系统)
半导体
热电材料
声子散射
化学
热导率
电子迁移率
极地的
散射
离子键合
电子
色散(光学)
电介质
电子能带结构
密度泛函理论
带隙
电阻率和电导率
光电子学
霍尔效应
载流子散射
格子(音乐)
化学物理
电导率
材料科学
作者
Zhonghao Xia,Michele Reticcioli,Yateng Wang,Yali Yang,Alessandro Stroppa,Jiangang He
摘要
High-performance thermoelectric (TE) materials are crucial for efficient waste-heat recovery and solid-state cooling technologies. A persistent challenge in TE materials design arises from the strong interdependence among the electrical conductivity (σ), Seebeck coefficient (S), and lattice thermal conductivity (κL). Layered compounds can effectively suppress κL along the cross-plane direction owing to weak interlayer interactions; however, they often suffer from low carrier mobility (μ) caused by limited band dispersion and strong polar optical phonon (POP) scattering. Here, we perform high-throughput density functional theory calculations to screen 236 layered semiconductors and identify candidates with low effective mass (m*) and weak POP scattering. We identify 23 compounds with high cross-plane μ, among which 14 exhibit large power factors (S2σ). Notably, GaGe2Te stands out with exceptionally high cross-plane σ and power factor, enabled by a favorable combination of small m* and a small ionic dielectric constant. Simultaneously, GaGe2Te exhibits an ultralow cross-plane κL of 0.57 W m–1 K–1 at 300 K, originating from weak interlayer bonding and pronounced phonon anharmonicity. These results demonstrate an effective strategy to decouple electron and phonon transport in layered materials by mitigating POP scattering, thereby providing a promising pathway toward high-performance thermoelectric materials.
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