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Holographic techniques allow for the construction of 3D images by controlling the wave front of light beams. Huang et al.develop ultrathin plasmonic metasurfaces to provide 3D optical holographic image reconstruction in the visible and near-infrared regions for circularly polarized light.

Metasurfaces offer an approach for computer generated holograms with good efficiency and ease of fabrication. Here, Ye et al.report on spin and wavelength multiplexed nonlinear metasurface holography, showing construction of holographic images using fundamental and harmonic generation waves of different spins.

The wide range of properties encountered in metamaterials make them promising for numerous optical applications. Chenet al. build a plasmonic flat metamaterial lens with an abrupt phase change that functions as a convex lens for one handedness of light and a concave lens for the other.

A concept for the phase control of the nonlinear susceptibility using the left- and right-circular polarization basis for fundamental and harmonic generated light is introduced and tested using metasurfaces containing plasmonic antennas.

Photonic metasurfaces can be used to control the polarization, phase and amplitude of light. Nonlinear metasurfaces enable giant nonlinear optical chirality, realization of the geometric Berry phase, wavefront engineering, and optical switching and modulation, and hold potential for on-chip applications.

Previous demonstrations of cloaking, where objects are rendered invisible at certain frequencies, have been limited to the microwave regime. Moving us a significant step closer to invisibility in a region that can been seen by humans, a cloaking device has now been demonstrated for a broad range of frequencies in the near-infrared.

Using a metasurface comprising an array of nanorods with different orientations and a backreflector, a hologram image can be obtained in the visible and near-infrared with limited loss of light intensity.

Linearly polarized light can be used to generate a rotational force in a plasmonic nanostructure that is capable of rotating a much larger microdisk.

The change in pitch of a passing car engine is a classic example of the translational Doppler effect, but rotational Doppler shifts can also arise, as shown for circularly polarized light passing through a spinning nonlinear optical crystal.

A key challenge is to realize ultracompact lasers that can directly generate coherent optical fields at the nanometre scale, far beyond the diffraction limit. Surface plasmons could be used to tightly confine light on very short lengthscales, but so far this approach has been hampered by ohmic losses at optical frequencies. The experimental demonstration of nanometre-scale plasmonic lasers is now reported, realized using a hybrid plasmonic waveguide — these lasers can generate optical modes a hundred times smaller than the diffraction limit.

Dielectric metalenses made of high-index materials can compensate material dispersion to achieve broadband imaging in the visible.

Grey-scale lithography has been used to make Luneburg and Eaton lenses that have lower losses than previously reported plasmonic elements.

A metasurface is used to generate a hybrid grafted perfect vector vortex beam, which can be dynamically controlled with a half waveplate. The beam has spatially variant rates of polarization change due to the involvement of more topological charges.

Pharmacological probes are important tools for exploring disease biology and discovering new therapies. Often molecules of insufficient quality are used instead, leading to spurious and misleading results. The Boehringer Ingelheim open innovation portal opnMe.com addresses this deficiency by sharing extensively validated pharmacological probes with the scientific community.

Asymmetric parametric generation of light in nonlinear metasurfaces is enabled by nonlinear dielectric resonators in translucent metasurfaces. Upon infrared illumination, different and independent visible light images are detected for ‘forwards’ versus ‘backwards’ operation.

Artificial intelligence (AI) tools are increasingly being applied in drug discovery. This article presents the views of a group of international experts on the ‘grand challenges’ in small-molecule drug discovery with AI, including obtaining appropriate data sets, generating new hypotheses, optimizing in a multi-objective manner, reducing cycle times and changing the research culture.

We theoretically and experimentally show a 900-fold boosting of optical THG emission in silicon metasurfaces using a novel type of nonlinear multi-mode Fano mechanism.