Recently, the first
synthesis of a freestanding monolayer amorphous
carbon (MAC) was reported. MAC is a pure carbon structure composed
of randomly distributed five, six, seven, and eight atom rings. MAC
is structurally very stable and highly fracture resistant. Its electronic
properties are similar to those of boron nitride. In this work, we
have investigated the mechanical properties and thermal stability
of MAC models using fully atomistic reactive molecular dynamics simulations.
For comparison purposes, the results are contrasted against pristine
graphene (PG) models of similar dimensions. Our results show that
MAC and PG exhibit distinct mechanical behavior and fracture dynamics
patterns. While PG, after a critical strain threshold, goes directly
from elastic to brittle regimes, MAC shows different elastic stages
between these two regimes. MAC is thermally stable up to 5368 K, which
is close to the melting point of PG (5643 K). These exceptional physical
properties make MAC-based materials promising candidates for new technologies,
such as flexible electronics.
At the molecular scale, bone is mainly constituted of type-I collagen, hydroxyapatite, and water. Different fractions of these constituents compose different composite materials that exhibit different mechanical properties at the nanoscale, where the bone is characterized as a fiber, i.e., a bundle of mineralized collagen fibrils surrounded by water and hydroxyapatite in the extra-fibrillar volume. The literature presents only models that resemble mineralized collagen fibrils, including hydroxyapatite in the intra-fibrillar volume only, and lacks a detailed prescription on how to devise such models. Here, we present all-atom bone molecular models at the nanoscale, which, differently from previous bone models, include hydroxyapatite both in the intra-fibrillar volume and in the extra-fibrillar volume, resembling fibers in bones. Our main goal is to provide a detailed prescription on how to devise such models with different fractions of the constituents, and for that reason, we have made step-by-step scripts and files for reproducing these models available. To validate the models, we assessed their elastic properties by performing molecular dynamics simulations that resemble tensile tests, and compared the computed values against the literature (both experimental and computational results). Our results corroborate previous findings, as Young’s Modulus values increase with higher fractions of hydroxyapatite, revealing all-atom bone models that include hydroxyapatite in both the intra-fibrillar volume and in the extra-fibrillar volume as a path towards realistic bone modeling at the nanoscale.
We investigated through fully atomistic molecular dynamics simulations, the mechanical behavior (compressive and tensile) and energy absorption properties of two families (primitive (P688 and P8bal) and gyroid (G688 and G8bal)) of carbon-based schwarzites. Our results show that all schwarzites can be compressed (with almost total elastic recovery) without fracture to more than 50%, one of them can be even remarkably compressed up to 80%. One of the structures (G8bal) presents negative Poisson's ratio value (auxetic behavior). The crush force efficiency, the stroke efficiency and the specific energy absorption (SEA) values show that schwarzites can be effective energy absorber materials. Although the same level of deformation without fracture observed in the compressive case is not observed for the tensile case, it is still very high (30-40%). The fracture dynamics show extensive structural reconstructions with the formation of linear atomic chains (LACs).
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