A new lens technology that could be produced using standard computer-chip technology is emerging and could replace the bulky layers and complex geometries of traditional curved lenses. Flat lenses, unlike their traditional counterparts, are relatively lightweight and based on optical nanomaterials known as metasurfaces. When the subwavelength nanostructures of a metasurface form certain repeated patterns, they mimic the complex curvatures that refract light, but with less bulk and an improved ability to focus light with reduced distortion. However, most of these nanostructured devices are static, which limits their functionality.
Federico Capasso, an applied physicist at Harvard University, USA, and Daniel Lopez, group leader of nanofabrication and devices at Argonne National Laboratory, USA, have developed a device that integrates mid-infrared spectrum metalenses onto microelectromechanical systems (MEMS). The researchers report their findings in APL Photonics.
MEMS is a circuit-based technology that incorporates microelectronics, like those found in computer chips, and includes mechanical microstructures like actuators and gears. Ubiquitous in everything from cell phones to airbags, biosensing devices, appliances and optics, MEMS are fabricated using the same techniques used for integrated circuits on typical computer chips.
“Dense integration of thousands of individually controlled lens-on-MEMS devices onto a single silicon chip would allow an unprecedented degree of control and manipulation of the optical field”, Lopez said.
The researchers formed the metasurface lens using standard photolithography techniques on a silicon-on-insulator wafer with a 2-µm-thick top device layer, a 200-nm buried-oxide layer and a 600-µm-thick handle layer. Then, they placed the flat lens onto a MEMS scanner, essentially a micromirror that deflects light for high-speed optical path length modulation. They aligned the lens with the MEMS’ central platform and fixed them together by depositing small platinum patches.
“Our MEMS-integrated metasurface lens prototype can be electrically controlled to vary the angular rotation of a flat lens and can scan the focal spot by several degrees”, Lopez said. “Furthermore, this proof-of-concept integration of metasurface-based flat lenses with MEMS scanners can be extended to the visible and other parts of the electromagnetic spectrum, implying the potential for application across wider fields, such as MEMS-based microscope systems, holographic and projection imaging, LIDAR (light detection and ranging) scanners and laser printing.”
When electrostatically actuated, the MEMS platform controls the angle of the lens along two orthogonal axes, allowing the scanning of the flat lens focal spot by about 9° in each direction. The researchers estimate that the focusing efficiency is about 85%.
“Such metalenses can be mass produced with the same computer-chip fabrication technology and in the future, will replace conventional lenses in a wide range of applications”, Capasso said.