Flat Lenses With a Twist

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Ultrathin nanostructured films that control light propagation provide a way of integrating optical components into portable and wearable electronic devices. Twisting a stack of such films offers a simple means to control their behavior and performance, KAUST research shows.

A surface patterned with an array of nanometer-scale structures can change the properties of light passing through it. Each element in the array behaves like a tiny antenna that controls the light’s local phase; that is the relative position of the light wave in its oscillatory cycle. These ultrathin layers are called metalenses because they can focus light just like a conventional, albeit much thicker, glass lens, while being more functional.

“This technology can arbitrarily shape the light pixel by pixel, which is impossible for conventional lenses because of fabrication limitations,” says graduate student Ronghui Lin. “The metalens technology has the potential to replace the huge lens assemblies used in professional reflex cameras with a lens as thin as a postcard.”

One challenge in the development of multifunctional metalenses is their limited efficiency. One possible way to improve this is to stack the metalens. By doing this, Lin and his supervisor, Xiaohang Li, discovered that new phenomenon can be enabled when one metalens is laid on top of another.

The team looked at a metalens with a surface covered in an array of fins or cylinders with an elliptical cross section. By varying the relative orientation of these fins, the lens can add a geometric phase to incoming circularly polarized light. “Consider the rotation of the hands of a clock, which return to the same place every day,” explains Lin. “The rotation angle of these nanofins works in a similar manner. When light passes through these structures, its phase or ‘time’ is changed.” The degree of change depends on the nanofin rotation. This is a powerful tool to manipulate circularly polarized light.

Lin and Li used a mathematical method called finite-difference time-domain simulations to model light propagation in a metalens system comprising two stacked phase elements. Their results showed that by twisting the relative alignment of the two layers, a phenomenon similar to the Moiré effect can be observed (see image below). The team used this phenomenon to develop a bifocal metalens with controllable focal length and intensity ratio. “We believe this multilayer metalens architecture could also apply to other systems and achieve more complicated functionalities,” says Lin.


A Moiré pattern can be formed when two arrays are overlapped and rotated.



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