A new publication from Opto-Electronic Advances, 10.29026/oea.2023.220060 discuss time-sequential color code division multiplexing holographic display with metasurface.
Directly reconstructing the physical wavefront of objects in target scene for watched naturally by human eyes, holographic display is considered as one of ultimate display technology. Spatial light modulators (SLMs) are core devices in display systems to manipulate the illuminating light. However, current commercial SLMs have several issues, such as too large size of pixel, restricted capability of modulation, diffractive noise and so on, which has become the bottleneck for the development of holographic display. A new element or device should be introduced to take the place of SLMs.
As the novel nanooptical element, metasurface consists of subwavelength artificial structures that has strong interaction with light. Consequently, it can realize specific functions that are impossible for traditional optical elements and devices by excellently manipulating the amplitude, phase, polarization, wavevector and other parameters of light. Combined with holography who has the properties of redundancy and robustness, optical metasurfaces own more degrees of freedom and flexibility for design and applications. Scholars have donated a lot to increase the multiplexing degrees by considering the polarization, orbital angular momentum, angle and other factors, which boosts the information capacity and density of metasurfaces. Although metasurfaces have so many advantages and a plenty of effort has been put into, but it is still uneasy task to fabricate a metasurface for the feature size of hundreds of nanometers. As the result, it is one of biggest challenges to realize dynamic modulation by metasurfaces, specially for color holographic display, which requires the element can offers different manipulation at the working wavelengths of R, G and B.
The authors of this article propose multiwavelength code division multiplexing (CDM) metasurface holography via combining birefringent metasurface and introduce the concept of CDM from communication technology. According to the basic principle of CDM, a series of codes are selected as "keys" to encode and decode the information. The authors optimized the coded reference and introduce multiwavelength channels to encode the information of both references and target scene into a single metasurface for optical data recording and reconstruction in a large number of channels.
Deeply analyzing the mechanism of color CDM and studying the properties of holographic wavefront encoding, the authors brought non-orthogonal color-coded references into CDM metasurface holography. A multichannel iterative optimization algorithm is presented and utilized to encode three groups of images and color code reference into the metasurface hologram. Titanium dioxide nanorods were designed to provide two linear polarization channels working at visible range because of the birefringence of the structures. The geometric sizes of nanorod are scanned to optimize the electromagnetic response of nanostructure, and then the sample data can be obtained for fabricating the metasurface by electron beam lithography and reactive ion etching.
In experimental verification, the authors successfully encoded information in 48 independent channels into a single metasurface, and only the correct color-coded illumination with correct polarization state can read out the recorded information. A time division multiplexing color illumination system was built with a digital micromirror device (DMD), and the target information is decoded frame by frame and one wavelength to another via time-sequentially specific illuminating and loading corresponding code pattern on DMD. And then, the color holographic video display can be achieved. The method demonstrates high density of information storage, high compacity with other multiplexing method, high flexibility in design and high security of optical data, which is promising to be applied into the field of display, information storage, optical encryption, multifunction dynamic manipulation and others.
Keywords: metasurface / color holography / dynamic display / code division multiplexing
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The joint research group is from Beijing Engineering Research Center of Mixed Reality and Advanced Display, School of Optics and Photonics, Beijing Institute of Technology and Micro-Nano Photonics Laboratory of Harbin Institute of Technology, Shenzhen. The main study areas of the group include physical mechanisms and applications of novel micro-nano optical elements, light field manipulations, diffractive optics, holography, information optics, principle and elements in novel display, and functional optoelectronic nano materials and devices and so on.
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Opto-Electronic Advances (OEA) is a high-impact, open access, peer reviewed monthly SCI journal with an impact factor of 8.933 (Journal Citation Reports for IF2021). Since its launch in March 2018, OEA has been indexed in SCI, EI, DOAJ, Scopus, CA and ICI databases over the time and expanded its Editorial Board to 36 members from 17 countries and regions (average h-index 49).
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Article reference: Li X, Chen QM, Zhang X, Zhao RZ, Xiao SM et al. Time-sequential color code division multiplexing holographic display with metasurface. Opto-Electron Adv 6, 220060 (2023). doi: 10.29026/oea.2023.220060