Abstract In this research, a two-dimensional (2-D) finite-difference time-domain (FDTD) analysis method is applied to study the coupling between nano-plasmonic cylinders and mode characteristics 1-D nano-plasmonic waveguides. The Drude model for metallic material dispersion is implemented into the FDTD algorithm along with the dispersive uniaxial perfectly matched layer (UPML) as the absorbing boundary condition for the computational domain. For the modeling of the curved surfaces for the dispersive materials, we first compare the index-average scheme with the conformal scheme. We then apply the conformal scheme to analyze the total scattering cross section (TSCS) of the nano-plasmonic cylinders. The relation between the near field intensity and the TSCS of 1-D cylinder arrays are discussed. We calculate the TSCS and the near field intensity by changing the size of the cylinder radius, the distance between the neighboring cylinders, and the direction of the incidence wave. Rather than applying frequency-domain methods, we try to use the FDTD method to analyze the guiding conditions for 1-D nano-plasmonic cylinder and film arrays. For the cylinder arrays, we compare the results calculated by the FDTD method with those by the finite-element method (FEM) in our group. For the film arrays, we vary the thickness of the films and observe the change of the dispersion curves and magnetic field distributions of each guided mode.