Gold nanoparticle thin films, composed of gold cores and organic ligands, have been used for a variety of applications because of their exceptional electronic, optical, and mechanical properties. Numerous studies explored their tenability of the elastic and electronic transport properties. However, experimental studies did not indicate clear nanoscale mechanisms for their tunable properties. In this research, molecular dynamics simulations are used to explore the nanoscale features and mechanical responses of alkanedithiol cross-linked gold nanoparticle thin films. We employed an approach to construct the cross-linked thin film models with different ligand chain lengths, nanoparticle core sizes, and ligand grafting density. The thin films with 3-D fcc superlattice structure are stable and have interparticle distances and elastic moduli consistent with the experiment. The results show that shorter ligand length, larger core size, or dense ligand coverage lead to stiffer thin films. By observing the ligand structure at nanoscale, we conclude that the number of all-trans bridge linkers is positively correlated with the thin film’s stiffness. Understanding these nanoscale details can provide us deeper insights into the mechanical properties of the cross-linked gold nanoparticle thin film.