One of the most fascinating predictions of the theory of general relativity
is the effect of gravitational lensing, the bending of light in close proximity
to massive stellar objects. Recently, artificial optical materials have been
proposed to study the various aspects of curved spacetimes, including light
trapping and Hawking's radiation. However, the development of experimental toy
models that simulate gravitational lensing in curved spacetimes remains a
challenge, especially for visible light. Here, by utilizing a microstructured
optical waveguide around a microsphere, we propose to mimic curved spacetimes
caused by gravity, with high precision. We experimentally demonstrate both
far-field gravitational lensing effects and the critical phenomenon in close
proximity to the photon sphere of astrophysical objects under hydrostatic
equilibrium. The proposed microstructured waveguide can be used as an
omnidirectional absorber, with potential light harvesting and microcavity
applications.Comment: 17 pages, 4 figures. This work is published at Nature Photonics,
Published online: 29 September 201
Transformation optics has been used to propose various novel optical devices. With the help of metamaterials, several intriguing designs, such as invisibility cloaks, have been implemented. However, as the basic units should be much smaller than the working wavelengths to achieve the effective material parameters, and the sizes of devices should be much larger than the wavelengths of illumination to work within the light-ray approximation, it is a big challenge to implement an experimental system that works simultaneously for both geometric optics and wave optics. In this Letter, by using a gradient-index microstructured optical waveguide, we realize a device of conformal transformation optics (CTO) and demonstrate its self-focusing property for geometry optics and the Talbot effect for wave optics. In addition, the Talbot effect in such a system has a potential application to transfer digital information without diffraction. Our findings demonstrate the photon controlling ability of CTO in a feasible experiment system.
The past decade has witnessed remarkable progress in wavefront shaping, including shaping of beams in free space, of plasmonic wavepackets and of electronic wavefunctions. In all of these, the wavefront shaping was achieved by external means such as masks, gratings and reflection from metasurfaces. Here, we propose wavefront shaping by exploiting general relativity (GR) effects in waveguide settings. We demonstrate beam shaping within dielectric slab samples with predesigned refractive index varying so as to create curved space environment for light. We use this technique to construct very narrow non-diffracting beams and shape-invariant beams accelerating on arbitrary trajectories. Importantly, the beam transformations occur within a mere distance of 40 wavelengths, suggesting that GR can inspire any wavefront shaping in highly tight waveguide settings. In such settings, we demonstrate Einstein's Rings: a phenomenon dating back to 1936.
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