Irida-Graphene: A New 2D Carbon Allotrope

Several 2D carbon-based materials have been computationally designed in the last years due to the success achieved by graphene. Here, we propose a new 2D all-sp$^2$ carbon allotrope, named Irida-Graphene (IG), using a bottom-up approach. IG is composed of fused rings containing 3-6-8 carbon atoms....

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Veröffentlicht in:	arXiv.org 2022-08
Hauptverfasser:	Pereira Junior, M L, da Cunha, W F, Giozza, W F, R T de Sousa Junior, Ribeiro Junior, L A
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Sprache:	eng
Schlagworte:	Allotropy Carbon Density functional theory Graphene Modulus of elasticity Molecular dynamics Optical activity Optical properties Refractivity
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description	Several 2D carbon-based materials have been computationally designed in the last years due to the success achieved by graphene. Here, we propose a new 2D all-sp$^2$ carbon allotrope, named Irida-Graphene (IG), using a bottom-up approach. IG is composed of fused rings containing 3-6-8 carbon atoms. We employed density functional theory calculations and reactive (ReaxFF) molecular dynamics simulations to examine its mechanical, structural, electronic, and optical properties. Results showed that IG exhibits good dynamical and thermal stabilities. Its estimated elastic modulus varies between 80-113 GPa. IG is a metallic material and presents a Dirac cone above the Fermi level in the center of the band. The intense optical activity of IG is restricted to the infrared and violet regions. IG can act as a violet collector for photon energies of about 3.0 eV since it presents very low reflectivity and refractive index greater than one.
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subjects	Allotropy Carbon Density functional theory Graphene Modulus of elasticity Molecular dynamics Optical activity Optical properties Refractivity
title	Irida-Graphene: A New 2D Carbon Allotrope
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