In this thesis, the numerical results of overall absorption and scattering cross sections and cross sections per metal volume of Au nanorod (NRO), nanoring (NRI), and nanoshell (NS), based on the commonly used localized surface plasmon (LSP) resonance modes, with various sizes and aspect ratios (ARs) in the reasonable ranges, which are determined by the practical fabrication capability and application wavelength ranges, are compared. The results show that the overall absorption and scattering cross sections of NRO are generally smaller than those of NRI and NS. However, in terms of cross section per Au volume, those of NRO are the highest among the three types of Au nanoparticle (NP), followed by NRI and then NS. We also evaluate the effects of NP random orientation distribution in a solution or tissue in practical applications. It is found that with random orientation, the reduction range of extinction cross section depended on the geometry symmetry property of the electron oscillation axis in the concerned LSP resonance mode. Then, we designed an Au NRI to make the resonance wavelengths of its symmetric dipole mode and axial dipole mode the same by increasing the ring height. In such an Au NRI of a large ring height, the reduction ranges of scattering and absorption cross sections were significantly decreased.