Making copper, silver and gold fullerene cages breathe

Abstract

Abstract We show that optical properties change when the fullerene structures of Au32, Cu32 and Ag32 inflate and deflate. We first observe significant differences in the extinction spectra employing a classical approach based on the Green’s dyadic method. By means of real-time time-dependent density functional theory. We continue to calculate the optical spectrum (OP) via a δ-kick simulation, comparing results with the ground-state energetic property the HOMO–LUMO (HL) gap. Red-shift of the OP is expected as the fullerenes inflate, with only ±10% change in the size. As the fullerene breathes, a 0.8 eV shift in the first peak position could be observed in the gold nanoparticle. Ag has a smoother behaviour than both Au and Cu. We have also found changes in the optical spectra can not be directly interpreted as a result of changes in the HL gap.