Loke, Vincent L. Y.Mengüç, Mustafa Pınar2013-10-232013-10-232010-101084-7529http://hdl.handle.net/10679/298https://doi.org/10.1364/JOSAA.27.002293Due to copyright restrictions, the access to the full text of this article is only available via subscription.Evanescent waves on a surface form due to the collective motion of charges within the medium. They do not carry any energy away from the surface and decay exponentially as a function of the distance. However, if there is any object within the evanescent field, electromagnetic energy within the medium is tunneled away and either absorbed or scattered. In this case, the absorption is localized, and potentially it can be used for selective diagnosis or nanopatterning applications. On the other hand, scattering of evanescent waves can be employed for characterization of nanoscale structures and particles on the surface. In this paper we present a numerical methodology to study the physics of such absorption and scattering mechanisms. We developed a MATLAB implementation of discrete dipole approximation with surface interaction (DDA-SI) in combinationwith evanescent wave illumination to investigate the near-field coupling between particles on the surface and a probe. This method can be used to explore the effects of a number of physical, geometrical, and materialproperties for problems involving nanostructures on or in the proximity of a substrate under arbitrary illumination.engrestrictedAccessSurface waves and atomic force microscope probe-particle near-field coupling: discrete dipole approximation with surface interactionarticle27102293230300028251590002210.1364/JOSAA.27.002293Evanescent wavesOptics at Surfaces2-s2.0-77957888073