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Future display technologies such as virtual and augmented reality require higher pixel resolutions and optical contrast. However, the potential of state-of-the-art displays is limited by the individual pixel size to achieve necessary resolution. Researchers at the University of Stuttgart have now succeeded to observe switching processes at previously unattained nanometer resolution. It opens the door towards new and innovative ultra-high-resolution displays of the future. The journal Science Advances reports their groundbreaking work in its issue of May 08, 2020.
The size of pixels in state-of-the-art switchable optical devices is intrinsically limited by the fabrication of micrometer-sized transistors and spatial light modulators. To further decrease their size, several approaches are currently under debate and investigated in research labs all over the world. One promising route can be found in the field of nanoplasmonics. A plasmonic nanoparticle typically has sizes of only several tens of nanometers and can focus light into sub-wavelength dimensions with an extreme localization of electro-magnetic fields. By adjusting the size of such particles, their color appearance can be shifted through the entire visible spectral range. In combination with phase-transition materials their optical properties and their appearance can be tuned, colors can be turned on and off, and one can realize switchable colored plasmonic pixels with nanometers size.
One promising material for this purpose is magnesium. The well-known metal can, under external stimulus, hydrogenate to a dielectric insulator with an extreme optical material contrast. This makes it an ideal candidate for optically active and switchable systems such as dynamic holography, plasmonic color displays, or switchable metamaterials. So far, the optical switching from metallic magnesium to dielectric magnesium hydride with hydrogen is strongly limited by intrinsic material factors and obstacles such as the volume expansion of the material, poor cyclability, and limited diffusion coefficients.
Switching processes at previously unattained nanometer Resolution
Researchers from the 4th Physics Institute at the University of Stuttgart have succeeded for the first time to image and watch the switching process of this smart material with the required nanometer resolution to understand and analyze the influence of nanoscale morphology on the hydrogenation. In his experiment, Julian Karst from the group of Harald Giessen uses free-standing magnesium to image in-situ its nanoscale optical and morphological properties. The measurements reveal an extreme influence of morphology on the nanoscale optical switching mechanism and highlight the possibility for significant future improvements of the optical switching performance.
Towards 3D holographic Virtual Reality
Harald Giessen believes that their published work will help in the future to develop, design, and analyze high-performance pixelated smart material optical devices with nanometer-sized pixels. Furthermore, as magnesium is also a very promising candidate for hydrogen storage, he believes that the results on the diffusion processes on the nanometer scale will aid the improvement of the hydrogen storage efficiency. It might pave the way to realize 3D holographic virtual reality glasses in a few years.
Prof. Harald Giessen, Julian Karst, University of Stuttgart, 4th Physics Institute, Phone +49 711 685-65111, E-Mail giessen@pi4.uni-stuttgart.de
J. Karst, F. Sterl, H. Linnenbank, T. Weiss, M. Hentschel, H. Giessen: Watching in situ the hydrogen diffusion dynamics in magnesium on the nanoscale, Sci. Adv. 6, eaaz0566 (2020). DOI: 10.1126/sciadv.aaz0566, https://advances.sciencemag.org/content/6/19/eaaz0566
https://www.pi4.uni-stuttgart.de/img/news/news_2020/2020-05-08_High_Resolution_D... (Movie)
Visualization of the topography of magnesium with nanometer resolution covered with an optical scatt ...
University of Stuttgart / PI 4
Dynamics of the magnesium hydride phase formation in magnesium with nanometer resolution captured wi ...
University of Stuttgart / PI 4
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