Physical properties of Cu nanoparticles: A molecular dynamics study

• Solid and liquid properties of Cu nanoparticles are studied.
• Molecular dynamics utilizing the Quantum Sutton Chen potential is used in this work.
• Melting temperatures of nanoparticles are strongly depended on nanoparticle sizes.
• Heat capacity, radial distribution function and diffusion coefficients are studied.
• Structures of nanoparticles are analyzed by Lindemann and Honeycutt–Andersen index.

Thermodynamical, structural and dynamical properties of Cu nanoparticles are investigated by using Molecular Dynamics (MD) simulations at various temperatures. In this work, MD simulations of the Cu-nanoparticles are performed by means of the MPiSiM codes by utilizing from Quantum Sutton-Chen (Q-SC) many-body force potential to define the interactions between the Cu atoms. The diameters of the copper nanoparticles are varied from 2 nm to 10 nm. MD simulations of Cu nanoparticles are carried out at low and high temperatures to study solid and liquid properties of Cu nanoparticles. Simulation results such as melting point, radial distribution function are compared with the available experimental bulk results. Radial distribution function, mean square displacement, diffusion coefficient, Lindemann index and Honeycutt–Andersen index are also calculated for estimating the melting point of the Copper nanoparticles.