Researchers from Seoul National University have developed a folded lens system using metasurfaces to dramatically reduce the volume of cameras. By arranging metasurfaces on a glass substrate so that light can be reflected and moved around in the substrate in a folded manner, the team realized a lens system with a thickness of 0.7 mm. Traditional cameras are designed to stack multiple glass lenses to refract light when capturing images. While this structure has provided excellent high-quality images, the thickness of each lens and the wide spacing between lenses increases the overall bulk of the camera, making it difficult to apply to devices that require ultra-compact cameras, such as VR and AR devices, smartphones, endoscopes, drones, and more. To address this limitation, the researchers developed an ultra-thin camera system that reduces the thickness of a conventional lens system by less than half, using a new lens module design that incorporates metasurfaces. Metasurfaces, which are being touted as the next generation of nano-optical devices, have the ability to precisely control the three properties of light — intensity, phase, and polarization — on a pixel-by-pixel basis. This is because the nanostructures that make up a metasurface are arranged in periods of a few hundred nanometers (nm), which is shorter than the wavelength of light. A schematic of a next-generation ultra-thin camera that utilizes metasurfaces, a nano-optical device, to secure light paths: By aligning metasurfaces horizontally on a glass substrate, light reflects multiple times within the substrate, securing space-efficient light paths in a folded manner. Courtesy of Seoul National University College of Engineering. “Our research focuses on efficiently utilizing the lens space by using metasurfaces,” said Taewon Choi, co-first author of the study. “The folded lens system is very thin, unlike conventional systems that are thick due to the combination of multiple lenses, so it will play an important role in the virtual and augmented reality industry, where device miniaturization and light weight are essential.” According to the team, by designing a metasurface optimized for a specific wavelength (852 nm) and arranging multiple sheets horizontally on a glass substrate, light can be reflected multiple times inside the substrate, thereby space-efficiently securing the light paths in a folded manner. The team presented a structure for a miniaturized camera that captures images with a system of thin, folded lens module that adjust the path of light. The system not only overcomes the physical limitations of thick conventional lens modules, but also delivers superior image quality. This is because it provides a 10-degree field of view within a very small system footprint of 0.7 mm thick, and delivers high-resolution images close to the diffraction limit at an aperture of f/4 and a wavelength of 852 nm. Thanks to these strong competitive advantages, the miniaturized camera technology developed by the researchers is expected to be widely applied in various advanced optical device industries such as VR and AR devices, smartphones, medical endoscopes, and miniaturized drones. “This research is significant in that it provides a creative breakthrough to innovatively reduce the thickness of cameras by introducing nano-optical devices,” said Youngjin Kim, first author of the paper. “We will continue our research to lead the innovation of thin and light cameras with metasurfaces that combine excellent performance and industrial benefits thanks to their nanometer-scale light tuning freedom and fabrication through semiconductor processes.” The research was published in Science Advances (www.doi.org/10.1126/sciadv.adr2319).