Anomalous properties of spark plasma sintered boron nitride solids

Hexagonal boron nitride (h-BN) is brittle, however, its atomic-scale structural engineering can lead to unprecedented physical properties. Here we report the bulk synthesis of high-density crystalline h-BN solids by using high-temperature spark plasma sintering (SPS) of micron size h-BN powders. In...

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Main Authors Biswas, Abhijit, Serles, Peter, Alvarez, Gustavo A, Schimpf, Jesse, Hache, Michel, Kong, Jonathan, Demingos, Pedro Guerra, Yuan, Bo, Pieshkov, Tymofii S, Li, Chenxi, Puthirath, Anand B, Gao, Bin, Gray, Tia, Zhang, Xiang, Murukeshan, Jishnu, Vajtai, Robert, Dai, Pengcheng, Singh, Chandra Veer, Howe, Jane, Zou, Yu, Martin, Lane W, Clancy, James Patrick, Tian, Zhiting, Filleter, Tobin, Ajayan, Pulickel M
Format Journal Article
LanguageEnglish
Published 09.05.2024
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Summary:Hexagonal boron nitride (h-BN) is brittle, however, its atomic-scale structural engineering can lead to unprecedented physical properties. Here we report the bulk synthesis of high-density crystalline h-BN solids by using high-temperature spark plasma sintering (SPS) of micron size h-BN powders. In addition to the high mechanical strength and ductile response of such materials, we have obtained anomalous values of dielectric constant beyond theoretical limits, high thermal conductivity, and exceptional neutron radiation shielding capability. Through exhaustive characterizations we reveal that SPS induces non-basal plane crystallinity, twisting of layers, and facilitates inter-grain fusion with a high degree of in-plane alignment across macroscale dimensions, resulting in near-theoretical density and anomalous properties. Our findings highlight the importance of material design, via new approaches such as twisting and interconnections between atomically thin layers, to create novel ceramics with properties that could go beyond their intrinsic theoretical predictions.
DOI:10.48550/arxiv.2405.06007