Fullwave Maxwell inverse design of axisymmetric, tunable, and multi-scale multi-wavelength metalenses
Christiansen, Rasmus E., Lin, Zin, Roques Carmes, Charles, Salamin, Yannick, Kooi, Steven E., Joannopoulos, John D., Soljačić, Marin, Johnson, Steven G.
Abstract
We demonstrate new axisymmetric inverse-design techniques that can solve problems radically different from traditional lenses, including reconfigurable lenses (that shift a multi-frequency focal spot in response to refractive-index changes) and widely separated multi-wavelength lenses (λ = 1 µm and 10 µm). We also present experimental validation for an axisymmetric inverse-designed monochrome lens in the near-infrared fabricated via two-photon polymerization. Axisymmetry allows fullwave Maxwell solvers to be scaled up to structures hundreds or even thousands of wavelengths in diameter before requiring domain-decomposition approximations, while multilayer topology optimization with ∼10[superscript 5] degrees of freedom can tackle challenging design problems even when restricted to axisymmetric structures.