Litcius/Paper detail

Hardening of fcc hard-sphere crystals by introducing nanochannels: Auxetic aspects

Jakub W. Narojczyk, Konstantin V. Tretiakov, Jerzy Smardzewski, Krzysztof W. Wojciechowski

2023Physical review. E27 citationsDOI

Abstract

Tailoring the materials for a given task by modifying their elastic properties is attractive to material scientists. However, recent studies of purely geometrical atomic models with structural modifications showed that designing a particular change to achieve the desired elastic properties is complex. This work concerns the impact of nanochannel inclusions in fcc hard sphere crystal on its elastic properties, especially auxetic ones. The models containing six nanochannel arrays of spheres of another diameter, oriented along the [110]-direction and its symmetric equivalents, have been studied by Monte Carlo simulations in the isothermal-isobaric (NpT) ensemble using the Parinello-Rahman approach. The inclusions have been designed such that they do not affect the cubic symmetry of the crystal. The elastic properties of three different models containing inclusions of various sizes are investigated under four thermodynamic conditions. We find that six nanochannels filled with hard spheres of larger diameter increase system stiffness compared with the fcc crystal without nanoinclusions. The current finding contrasts the recently reported results [J.W. Narojczyk et al. Phys. Status Solidi B 259, 2200464 (2022)0370-197210.1002/pssb.202200464], where the fcc hard sphere crystal with four nanochannels shows reduced stiffness compared to the system without nanoinclusions. Moreover, the six nanochannel models preserve auxetic properties in contrast to the fcc hard sphere crystal with four nanochannel arrays, which loses auxeticity.

Topics & Concepts

AuxeticsMaterials scienceSPHERESStiffnessCrystal (programming language)QuasicrystalHard spheresCrystal structureMonte Carlo methodCondensed matter physicsPhysicsComposite materialThermodynamicsCrystallographyChemistryMathematicsAstronomyStatisticsComputer scienceProgramming languageCellular and Composite StructuresMaterial Dynamics and PropertiesBlock Copolymer Self-Assembly