Construct Amorphous Polymer Interface to Enhance the Thermoelectric Performance of Commercial Bi0.5Sb1.5Te3 Materials

Li, Shuankui; Wang, Liangliang; Ma, Danning; Jiang, Yuanxin; Zhang, Jiye; Guo, Kai

doi:10.1021/acsami.3c17859

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.3c17859

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Construct Amorphous Polymer Interface to Enhance the Thermoelectric Performance of Commercial Bi_0.5Sb_1.5Te₃ Materials

Shuankui Li,

Liangliang Wang,

Danning Ma

et al.

Abstract: Interfaces, such as grain boundaries and phase boundaries in thermoelectric (TE) materials, play a crucial role in the carrier/phonon transport. Accurate control of the features of interfaces, including composition, crystalline nature, and thickness may give rise to a promising pathway to break the trade-off between phonon and carrier transport properties, which is essential to design high-performance TE materials. In this work, the amorphous polymer interface (API) layer is introduced to the ptype commercial … Show more

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Cited by 2 publications

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Significant enhancement of bi-directional ultrahigh thermal conductivity in polymer composites fabricated via Polyetherimide@Silver core–shell structured microspheres

Yang,

Zhao,

Wang

et al. 2024

Chemical Engineering Journal

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Significant enhancement of bi-directional ultrahigh thermal conductivity in polymer composites fabricated via Polyetherimide@Silver core–shell structured microspheres

Yang,

Zhao,

Wang

et al. 2024

Chemical Engineering Journal

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Enhanced Thermal Conductivity in Poly(ether imide)-Based Composites via Constructing Microscopic Segregated Networks with Ag-Bridged Graphite Nanoplatelets

Yang,

Zhao,

Wang

et al. 2024

ACS Appl. Polym. Mater.

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In recent years, polymer-based composites with high thermal conductivity have become important for the effective removal of accumulated heat in thermal management devices, though enhancing the thermal conductivity of poly(ether imide) materials remains challenging. Herein, to prepare high-thermalconductivity materials, silver nanoparticles are chemically reduced onto the surface of graphite nanoplates as hybrid fillers. Consequently, inspired by "cellular structures", segregated thermally conductive networks in composites are designed by mixing hybrid fillers and poly(ether imide) microspheres, followed by a hot-pressing process. Benefiting from the three-dimensional heat-transfer network and the bridging effect of silver nanoparticles, thermal conduction pathways are easily constructed, reducing interfacial heat resistance in the polymer matrix. At a hybrid filler loading of 40 wt %, the through-plane and in-plane thermal conductivities reach 4.7 and 11.3 W/m K, respectively. Moreover, the finite-element simulation reveals that the composites have high thermally conductive ability owing to the hybrid fillers, which offer highly effective pathways for phonon transmission. Besides, polymer composites exhibit a great electrical magnetic shielding performance (30.5 dB). In summary, this study provides a strategy for fabricating thermally conductive polymer-based composite materials for use in industrial heat dissipation devices.

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Construct Amorphous Polymer Interface to Enhance the Thermoelectric Performance of Commercial Bi_0.5Sb_1.5Te₃ Materials

Cited by 2 publications

References 30 publications

Significant enhancement of bi-directional ultrahigh thermal conductivity in polymer composites fabricated via Polyetherimide@Silver core–shell structured microspheres

Significant enhancement of bi-directional ultrahigh thermal conductivity in polymer composites fabricated via Polyetherimide@Silver core–shell structured microspheres

Enhanced Thermal Conductivity in Poly(ether imide)-Based Composites via Constructing Microscopic Segregated Networks with Ag-Bridged Graphite Nanoplatelets

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