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引用次数: 0
摘要
BiSbSeTe 是一种典型的多层化合物,可通过缺陷工程调节反位缺陷和阴离子空位来制造具有相同化学成分的 p-n 结。然而,由于电传输特性较差,n 型 BiSbSeTe 的热电性能受到限制。熵工程是拓展材料科学(包括热电领域)性能优化空间的一种新策略。在此,我们通过熵工程实现了 n 型 BiSbSeTe 热电性能的大幅提升。在晶格中同时引入了质量场波动和应力变化场,从而产生了额外的声子散射。此外,样品中还形成了纳米层状结构、纳米级间隙和孔洞。所有这些缺陷和纳米级结构都能有效地捕获声子。这些发现不仅为提高 n 型 BiSbSeTe 的热电性能提供了一种方法,还推动了利用化学成分相同的热电材料制造匹配良好的 p-n 结的应用前景。
Entropy engineering promotes thermoelectric performance while realizing P–N switchable conduction in BiSbSe1.5Te1.5
BiSbSeTe, a typical multi-layered compound, can be utilized to fabricate p-n junctions with the identical chemical composition by regulating the antisite defects and anion vacancies via defect engineering. However, the thermoelectric performance of n-type BiSbSeTe is limited due to poor electrical transport properties. Entropy engineering is a novel strategy for expanding the space of performance optimization in materials science, including the field of thermoelectric. Herein, we realize a largely enhanced thermoelectric performance for n-type BiSbSeTe by employing entropy engineering. Both mass field fluctuations and stress variations field are introduced simultaneously in the lattice, leading to additional phonon scattering. Moreover, nano-laminate structure, nanoscale interstices and holes are formed in the samples. All of these defects and nanoscale structures are especially efficient on trapping phonons. As a result, the optimizing electrical transport properties while maintaining low thermal conductivity are achieved, showcasing a peak of 0.54 at 475 K and a remarkable average of 0.45 between 300 and 550 K for n-type BiSbSeTe.These findings not only provide a way to enhance the thermoelectric performance of n-type BiSbSeTe but also push forward the promise of the applications in fabricating well-matched p-n junctions using thermoelectric materials with the identical chemical composition.
期刊介绍:
Materials Today Chemistry is a multi-disciplinary journal dedicated to all facets of materials chemistry.
This field represents one of the fastest-growing areas of science, involving the application of chemistry-based techniques to the study of materials. It encompasses materials synthesis and behavior, as well as the intricate relationships between material structure and properties at the atomic and molecular scale. Materials Today Chemistry serves as a high-impact platform for discussing research that propels the field forward through groundbreaking discoveries and innovative techniques.
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