Anisotropic Elastic Modulus, High Poisson's ratio and Negative Thermal Expansion of Graphynes and Graphdiynes
Sergio A. Hernandez, Alexandre F. Fonseca

TL;DR
This study uses molecular dynamics simulations to analyze the elastic and thermal properties of seven types of graphyne and graphdiyne structures, revealing their density dependence, anisotropic elasticity, and negative Poisson's ratios.
Contribution
It provides the first detailed investigation of the density dependence of elastic and thermal properties of all seven proposed GY and GDY types.
Findings
TEC increases quadratically with density.
Elastic modulus is highly sensitive to density.
Some non-symmetric GY and GDY have Poisson's ratios larger than one.
Abstract
Graphyne (GY) and graphdiyne (GDY) are two-dimensional one-atom-thick carbon allotropes highly considered to substitute graphene in electronic applications because of the prediction of non null band-gap. There are seven types of GY structures not yet fully investigated in literature. In this work, by means of classical molecular dynamics simulations, the Young's modulus, Poisson's ratio and linear thermal expansion coefficient (TEC) of all originally proposed seven types of GYs and corresponding GDYs are calculated. The dependence of these properties with the density of the structure is investigated for the first time. Quadratic increasing of the TEC of GY and GDY structures with density was found. The elastic modulus of GYs and GDYs were shown to be more sensitive to their density than general porous materials. In particular, non-symmetric structures are much softer along the armchair…
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