Single-Cell-Driven Tri-Channel Encryption Meta-Displays
[POSTECH research team led by Professor Junsuk Rho develops a tri-channel meta-display that generates different images by manipulating light polarization.]
[Streamlined fabrication and the ultra-compact size promise novel anti-counterfeiting applications and custom-made AR/VR displays]
Pockets of the POSTECH campus are turning into metaverse-ready spaces. Leveraging lessons learned from the COVID-19 pandemic, POSTECH has employed metaverse learning to enable students to conduct experiments and receive training the same way they do in the physical classroom. All they have to do is wear a virtual reality (VR) device before entering a laboratory or taking a tour of a nuclear power plant. Taking it a step further, what if the professor and the students simultaneously can see different content tailored to each other in class?
A POSTECH research team led by Professor Junsuk Rho (Department of Mechanical Engineering and Department of Chemical Engineering) with Ph.D. candidates Joohoon Kim and Junhwa Seong (Department of Mechanical Engineering) developed a tri-channel encryption meta-display. A multi-functional metasurface used in the display demonstrates different images by manipulating the incident polarization*1 of light, promoting the common use of ultra-compact displays and next-generation anti-counterfeiting devices, which project different images depending on where you look at them.
A metasurface is a sheet of artificial material with arrays of nanostructures, demonstrating a superb light steering capability. Each nanostructure is tinier than a wavelength, challenging researchers to find a way to save as many data sets in it as possible.
Furthermore, the conventional metasurface can contain only one piece of information in one nanostructure, requiring changes in shape or array to save multiple pieces of information. These changes required complicated designs fabrication process, causing inconvenience and additional costs. There was also a limit to reducing its size.
To overcome this issue, the research team combined amplitude modulation governed by Malus’s law*2 and the geometric phase manipulation*3 to fabricate single-cell-driven tri-channel encryption meta-displays. These have a simple structure, which is easy and inexpensive to make, and are very small (0.5 mm). The researchers succeeded in printing three different logos on the meta-displays
Professor Rho explained, “The study is an achievement that transcends the limitations of the conventional metasurface, which could not control the near-field and far-field light at the same time.” He added, “Our meta-display can be employed to build security devices that generate different images depending on the user’s orientation, or to customize VR/AR displays that show the professor and the student different screen content in the same classroom.”
The research, recently published in Advanced Science, was conducted with the support from the POSCO-POSTECH-RIST Convergence Research Center program funded by POSCO and the Pioneer Research Center program of the National Research Foundation of Korea.
1. Polarized light
light in which the vibrations occur in a single plane
2. Malus’s law
the intensity of plane-polarized light that passes through an analyzer varies as the angle between the plane of the polarizer and the transmission axes of the analyzer. The law was employed in this study for near-field intensity modulation.
3. Geometric phase
the phase of the generated light is adjusted continuously by using the degree of rotation of a single nanostructure. It was employed in this study for far-field phase modulation.