Abstract
We demonstrate digital plasmonic holography for direct in-plane imaging with propagating surface-plasmon waves. Imaging with surface plasmons suffers from the lack of simple in-plane lenses and mirrors. Lens-less digital holography techniques, however, rely on digitally decoding an interference pattern between a reference wave and an object wave. With far-field diffractive optics, this decoding scheme provides a full recording, i.e., a hologram, of the amplitude and phase of the object wave, giving three-dimensional information from a two-dimensional recording. For plasmonics, only a one-dimensional recording is needed, and both the phase and amplitude of the propagating plasmons can be extracted for high-resolution in-plane imaging. Here, we demonstrate lens-less, point-source digital plasmonic holography using two methods to record the plasmonic holograms: a dual-probe near-field scanning optical microscope and lithographically defined circular fluorescent screens. The point-source geometry gives in-plane magnification, allowing for high-resolution imaging with relatively lower-resolution microscope objectives. These results pave the way for a new form of in-plane plasmonic imaging, gathering the full complex wave, without the need for plasmonic mirrors or lenses.
Highlights
The interdisciplinary fields of plasmonics and nanophotonics allow manipulation of light with subwavelength precision
digital holographic microscopy18–25 (DHM) wherein the interference between a reference plasmon wave and an object plasmon wave forms a hologram on a smooth metallic surface
This holographic pattern was accessed in two ways: directly with a dual-probe near-field scanning optical microscope (NSOM, Nanonics MultiviewTM 4000) and indirectly by imaging the plasmon interaction with a dyedoped (Oxazine 750) fluorescent film of patterned polymethylmethacrylate (PMMA) electron-beam resist
Summary
The interdisciplinary fields of plasmonics and nanophotonics allow manipulation of light with subwavelength precision. SPs have a shorter wavelength than free-space light and extend only ~100 nm into their surrounding environment As they propagate, plasmons can scatter from surface defects, diffract around nanostructures, and cause interference effects with incident light, re-radiated light, or even other plasmons[2]. Plasmons can scatter from surface defects, diffract around nanostructures, and cause interference effects with incident light, re-radiated light, or even other plasmons[2] Because of these near-field effects, plasmons have been explored for many applications, including photovoltaics, enhanced spectroscopy, and sensing[3,4]. To better control these surface waves, there has been significant interest in developing the two-dimensional
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