Previously, saturable and suppressible scattering of single gold nanosphere have been reported. Saturable scattering means the decreasing reflectance as intensity of incident laser reached certain threshold; suppressible scattering means that one laser beam can suppress the reflectance of another laser with different wavelength. Both phenomena are based on continuous wave laser. Based on these nonlinearities ,non-bleaching superresolution microscopies are realized. Although it has been shown that saturation intensities depend on the wavelengths and localized surface plasmon resonance band, the mechanism of the nonlinear scattering is still unclear. In this thesis, we first summarize our previous experimental results of saturable and suppressible scattering. In small particle limit model is introduced to fit with experimental results of nonlinear scattering by single gold nanosphere. We have performed extensive wavelength (405~700nm), sizes (diameter 20~80nm), and polarization studies to characterize nonlinear scattering in a single nanoparticle. The results show the optical nonlinearity is enhanced by localized surface plasmon resonance, and the size is positively related to the nonlinearity behavior. No polarization dependence was observed. After extensive discussion of the possible candidates for microscopic mechanism, saturable and suppressible of gold nanosphere by continuous wave laser are attributed to thermo-optical effect, i.e. hot lattice of gold.