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MICRO-LEDs STACKED VERTICALLY TO SHARPEN DISPLAYS
Current flat panel displays for virtual reality use pixels that are visible to the naked eye, along with small bits of unlit dark space between each pixel that can appear as a black, mesh-like grid. Researchers from the Georgia Institute of Technology, in collaboration with researchers from the Massachusetts Institute of Technology (MIT) have developed a new process based on 2D materials to create LED displays with smaller and thinner pixels. Enabled by two-dimensional, materials-based layer transfer technology, the innovation could ultimately lead to clearer and more realistic LED displays.
Georgia Tech-Europe Professor Abdallah Ougazzaden and research scientist Suresh Sundaram collaborated with researchers from MIT to improve the current conventional LED manufacturing process. Instead of using prevailing processes based on laying red, green and blue (RGB) LEDs side by side, which limits pixel density, the team vertically stacked freestanding, ultrathin RGB LED membranes, achieving an array density of 5100 pixels per inch — the smallest pixel side reported to date (four microns) and reportedly the smallest stack height — all while delivering a full commercial range of colours. This ultra-small vertical stack was achieved via the technology of van der Waals epitaxy on 2D boron nitride developed at the Georgia Tech-Europe lab and the technology of remote epitaxy on graphene developed at MIT.
The study showed that thin and small pixelled displays can be enabled by an active layer separation technology using 2D materials such as graphene and boron to enable high array density micro-LEDs resulting in full-colour realisation of micro-LED displays. The two-dimensional, material-based layer transfer (2DLT) technique allows the reuse of epitaxial wafers; reusing this costly substrate could lower the cost for manufacturing smaller, thinner and more realistic displays.
“We have now demonstrated that this advanced 2D, materials-based growth and transfer technology can surpass conventional growth and transfer technology in specific domains, such as in virtual and augmented reality displays,” said Ougazzaden, the lead researcher for the Georgia Tech team.
These techniques were developed in metalorganic chemical vapour disposition (MOCVD) reactors, a key tool for LED production at the wafer scale. The 2DLT technique can be replicated on an industrial scale with high throughput yield. The technology has the potential to bring the field of virtual and augmented reality to the next level, enabling the next generation of immersive, realistic micro-LED displays.
Topological Waveguide Reduces Energy Consumption In Electronics
A team of researchers from the Institute for Materials Research at Tohoku University has developed an acoustic waveguide based on the mathematical concept of topology, which could lead to reduced energy consumption in many everyday electronic devices. Surface acoustic waves (SAW) are a type of acoustic wave where the vibration magnitude is focused on a material’s surface. SAWs can be excited and detected on piezoelectric substrates, crystals with the ability to generate electricity when compressed or vibrated. Electrical components, known as SAW devices, make use of this and provide frequency filtering and sensing in common electronic devices such as mobile phones and touch sensors. However, they consume a lot of energy, thus being a drain on battery life.
The team, which comprised Yoichi Nii and Yoshinori Onose from Tohoku University, created the topological waveguide as a solution to this problem. Waveguides are devices that carry or guide waves in a spatially confined area. Topological waveguides are a recent development that reduce energy loss and allow for manipulating waves in unique ways. The topological nature of the researchers’ waveguide reduces energy consumption and could also prolong the battery life of phones and other electronics.
The waveguide is also easy to create and compatible with current SAW device technology. “Implementing our waveguide involves simply fabricating nano-sized pillar patterns on the surface of the piezoelectric substrate,” Nii said.
The waveguide could drive further breakthroughs in quantum technologies. “SAW-based technologies have also attracted the attention of researchers exploring ways to push the boundaries of quantum computing,” Nii said.
The research findings were published in the journal Physical Review Applied
