In this research, we adopt the full-vectorial finite-element imaginary-distance beam propagation method (FV-FE-ID-BPM) based on the hybrid edge/nodal elements and incorporated with perfectly matched layers (PMLs) to analyze waveguide modes propagating on plasmonic waveguides composed of two parallel circular-cylinders named the double-nanowire, including that immersed in a uniform dielectric matrix and that supported by dielectric substrate. The effective refractive indices, propagation lengths, mode-field profiles, and effective mode areas are calculated for different parameters and structures over the wavelength range from 500 nm to 2000 nm. The double-nanowires immersed in uniform silica and in air are first investigated. The splitting into multiple modes due to the coupling between the two adjacent nanowires is examined by comparing with modal characteristics of the single nanowire. Different nanowire radii are also considered. The effect of including a supporting substrate is studied. Previous studies have given the fact that a single silver nanowire with a silica substrate possesses a silver/substrate guided mode and an air/silver leaky mode. The coupling phenomena of the double-nanowire case are demonstrated in this study, showing the resultant two silver/substrate guided modes and two air/silver leaky modes. Finally, the effect of using different substrate materials is discussed.