Publication Type : Journal Article
Publisher : Elsevier
Source : Journal of Materials Science & Technology, Volume 50, 1 August 2020, Pages 44-58, SCIE, IF: 10.319
Url : https://www.sciencedirect.com/science/article/abs/pii/S1005030220302334
Campus : Coimbatore
School : School of Artificial Intelligence - Coimbatore
Center : Computational Engineering and Networking
Year : 2020
Abstract : Doping in pristine 2D materials brings about the advantage of modulating wide range of mechanical properties simultaneously. However, intrinsic defects (such as Stone-Wales and nanopore) in such hybrid materials are inevitable due to complex manufacturing and synthesis processes. Besides that, defects and irregularities can be intentionally induced in a pristine nanostructure for multi-synchronous modulation of various multi-functional properties. Whatever the case may be, in order to realistically analyse a doped graphene sheet, it is of utmost importance to investigate the compound effect of doping and defects in such 2D monolayers. Here we present a molecular dynamics based investigation for probing mechanical properties (such as Young’s modulus, post-elastic behaviour, failure strength and strain) of doped graphene (C14 and Si) coupling the effect of inevitable defects. Spatial sensitivity of defect and doping are systematically analyzed considering different rational instances. The study reveals the effects of individual defects and doping along with their possible compounded influences on the failure stress, failure strain, Young’s modulus and constitutive relations beyond the elastic regime. Such detailed mechanical characterization under the practically relevant compound effects would allow us to access the viability of adopting doped graphene in various multifunctional nanoelectromechanical devices and systems in a realistic situation.
Cite this Research Publication : Gupta, K.K., Mukhopadhyay, T., Roy, A. and Dey, S., 2020. "Probing the compound effect of spatially varying intrinsic defects and doping on mechanical properties of hybrid graphene monolayers". Journal of Materials Science & Technology, Volume 50, 1 August 2020, Pages 44-58, SCIE, IF: 10.319