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Surface-plasmon waves have been utilized in many applications such as biological and chemical sensing and trapping,
sub-wavelength optics, nonlinear optics, optical communication and more. Controlling the shape and trajectory of these
waves is a key feature in enabling all of the above applications, and a challenging task. The fundamental challenges
resides in the different wave properties of surface plasmon waves, with comparison to free-space waves: First, coupling
a surface plasmon wave from a free-space wave requires a compensation for the missing momentum between the two
wave-vectors. Second, owing to the limited propagation length of surface plasmons and the limited measurement range
of their characterization tools, the resulting beams should be formed directly in the near-field. Third, unlike planar phase
plates, surface plasmons are excited over a finite propagation distance and therefore their phase cannot be simply defined
at a specific one-dimensional plane. Fourth, dynamic tools for controlling the wavefront of free-space beams, like
spatial-light-modulators, do not exist for surface plasmons. Here we demonstrate, both numerically and experimentally, a
robust holographic scheme that provides complete control over the amplitude and phase of surface-plasmons, thereby
enabling the engineering of any desired plasmonic light beam. We show how all of the above challenges can be
overcome by introducing a new class of binary plasmonic holograms, which are designed specifically for the near -filed.
We demonstrate a large variety of plasmonic beams, such as ”self-similar”, “non-diffracting", "self-accelerating", “selfhealing”,
paraxial and non-paraxial plasmonic beams, and also the dynamic generation of plasmonic bottle-beams for
micromanipulation of particles.
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