Highly efficient, miniature transparent holograms can be fabricated from dielectric metasurfaces consisting of arrays of silicon nanopillars. That's the achievement of a collaboration between the Australian National University in Canberra, Nanjing University in China and Oak Ridge National Laboratory in the US (Optica 3, 1504–1505; 2016).
Metasurfaces, ultrathin patterned substrates composed of an array of resonant subwavelength-sized elements that alter the phase, amplitude and polarization of incoming light, have become a highly active area of research in recent years. While many designs feature metals and rely on plasmonic effects, several research groups are now designing all-dielectric versions that operate by resonant scattering for realizing a variety of flat, planar optical devices such as waveplates, Q-plates and lenses.
Now, Lei Wang and co-workers report that it is possible to design and fabricate grayscale “metaholograms” that exploit the Mie resonances from dielectric nanostructures and operate in the near-infrared with very high transmission and diffraction efficiency (as shown in the above image of the kangaroo as an example).
“Our metaholograms produce grayscale high-resolution images and transmit over 90% of light with a diffraction efficiency over 99% at a 1600 nm wavelength,” say the authors of the paper. “This is the highest efficiency of any metahologram demonstrated to date reproducing grayscale images over a broad spectral range.” In this context, diffraction efficiency is defined as the power in the holographic image with respect to the total power transmitted by the metahologram.
The team's metaholograms consist of a dense array of silicon nanopillars of identical height (865 nm) but varying radii (79–212 nm) arranged in a square lattice with 750 nm period and has a total length of 0.75 mm. When illuminated, the metaholograms produce images 5 mm in size at a distance of 10 mm.
The metaholograms are fabricated by depositing poly-silicon on a silica wafer by low-pressure chemical vapour deposition. Electron-beam lithography and refractive ion etching are then used to create the desired nanopillar pattern. Each nanopillar acts as a pixel for the hologram, with a size-dependent phase delay.
The metaholograms have a spectral bandwidth of operation of 375 nm and the team says that the design approach is both scalable to the visible spectral region and potentially compatible with high-index materials such as Ge, GaAs, TiO2 or diamond.
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Graydon, O. Efficient holograms. Nature Photon 11, 76 (2017). https://doi.org/10.1038/nphoton.2017.7
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DOI: https://doi.org/10.1038/nphoton.2017.7