The resistivity change of thin firms of gold upon exposure to H2S has been employed to develop gas sensors that detect H2S. The exact mechanism by which H2S alters the conductivity of these films is not known. However, the adsorption and bonding of H2S on gold surfaces is clearly a critical step in the overall mechanism. In this study, we have explored the interaction of HS with the clean Au(l10) single-crystal surface. A variety of ultrahigh vacuum surface science techniques were used including X-ray photoelectron spectroscopy (XPS), low electron energy diffraction (LEED), temperature-programmed desorption (TPD), and high-resolution electron energy loss spectroscopy (HREELS). H2S was found to adsorb with a sticking probability of close to unity on the clean surface at 120 K. This adsorption produced a molecularly adsorbed H2S species on the surface that exhibits an SH stretching vibration at 2450 cm(-1) and an H2S scissor mode at 1150 cm(-1) in the HREEL spectra. TPD results suggest that the H2S desorbs directly as a molecule without decomposition at temperatures above 200 K. When defects are present in the Au surface or when the adsorbed H2S layer is irradiated with electrons, H2S will dissociate into adsorbed hydrogen and sulfhydryl (SH).