Abstract
Lightweight mechanically strong composite Al/BN nanotube materials may find applications in the automotive and space industries because addition of a few percent of the nanotubes considerably improves the mechanical properties of the Al matrix. At the same time, experiments indicate that bonding at the interface between Al and the nanotubes is rather weak, which limits the performance of the composites. To get precise microscopic knowledge of the atomic structure and bonding at the interface between the Al matrix and BN nanotubes and to suggest ways to improve the adhesion, we employ density functional theory with van der Waals exchange–correlation functionals and carry out first-principles calculations of the interface between the Al(111) surface and hexagonal BN sheets, mimicking BN nanotubes with large diameters. We estimate the bonding energy and the interfacial critical shear stress and compare the theoretical results to the experimental data. We further assess how point defects, such as atomic vacan...
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