So many people paid close attention to Au nanoparticles in recent years because of their high optical absorption property. It can be applied in engineering, biotechnology, energy technology, etc. For example, gold nanorods can be put in breast tumor cells, then using irradiation to trigger it, the cells nally explode and be eliminated. Now that the optical absorption of Au nanostructures is so interesting, we would like to investigate properties of them. The optical absorption spectra of Au nanostructures were calculated by using time evolution method which is based on time-dependent density functional theory. Here we present the spectra of three types of Au clusters; one is linear chain structures (Aun, n 9), another is planar structures from face-center cube (fcc) (001) plane, and the other is three-dimensional structures stacked by face-center crystal structure. In our study we discuss how cluster structure a ects absorption spectrum and the in uence of cluster size on absorption spectrum. Moreover, we also discuss the e ects of geometric optimization on absorption spectrum. The geometric shapes of these structures result in di erent absorption peaks and intensity. The linear chain clusters with three or more atoms can be regarded as collective plasmon because their absorption spectra have large absorption peaks and are dominated by those peaks.