Abstract:
Following the groundbreaking discovery of graphene, the scientific community has witnessed a
surge of interest in two-dimensional (2D) materials during recent times, remarkable capabilities
and versatility for technological applications. Apart from graphene, a lot of promising work has
been reported from other two-dimensional materials, including boron nitrides (like hBN, or "white
graphite"), dichalcogenides (like MoS2), silicene, germanane, stanene, etc. To use these materials
successfully in nanodevices and systems, it is important to figure out their elastic and mechanical
properties. This will help define the limits of useful applications for flexible electronics. Two
typical computational techniques for atomically thin models like 2D materials are molecular
dynamics and density functional theory. Using the concepts of classical mechanics, molecular
dynamics mimics the motion of atoms and molecules in a complicated system. In this study, the
effect of point and line defects on the 2D transition metal dichalcogenides (TMDs) namely
molybdenum ditelluride (MoTe2) were investigated using the Sandia National Laboratory's
Molecular Dynamics Program LAMMPS. Three distinct types of point defect structures were
investigated: a 2-tellurium vacancy structure, a 4-tellurium vacancy structure, and a 6-tellurium
vacancy accompanied by a 1-molybdenum vacancy structure. Line defects were placed along
armchair axis and zigzag axis. We characterized their mechanical characteristics, including axial
stiffness, ultimate strength, and ultimate strain, as well as their thermal behavior at temperatures
ranging from 1 Kelvin to 600 Kelvin, using atomistic computational techniques
Description:
Supervised by
Dr. Md. Rezwanul Karim,
Associate Professor,
Department of Civil and Environmental Engineering (CEE)
Islamic University of Technology (IUT)
Board Bazar, Gazipur, Bangladesh