Meta-hologram produces dual images and multiple colors (w/ Video)

January 9th, 2014 by Lisa Zyga in Nanotechnology / Nanophysics
Illustration of the meta-hologram, whose pixels consist of 6 x 6 gold nanocrosses of various lengths. The images NTU and RCAS are reconstructed by polarized light in orthogonal directions using a broadband light source. The technology has high potential for designing dual-image, full-color holograms. Credit: Wei Ting Chen, et al. ©2013 American Chemical Society


Illustration of the meta-hologram, whose pixels consist of 6 x 6 gold nanocrosses of various lengths. The images NTU and RCAS are reconstructed by polarized light in orthogonal directions using a broadband light source. The technology has high potential for designing dual-image, full-color holograms. Credit: Wei Ting Chen, et al. ©2013 American Chemical Society

(Phys.org) —Holograms have attracted wide attention for their ability to produce a realistic 3D image of an object by recording the object's light field and later reconstructing the light field on a 2D surface. Now researchers have fabricated a hologram using metamaterials that can produce dual holographic images of different colors on a single surface. The two images are generated by two orthogonal polarizations, while the colors are produced by the hologram's wide operation wave length range.

The researchers, Wei Ting Chen, et al., from institutions in Taiwan, the US, China, and Singapore, have published a paper on the meta- in a recent issue of Nano Letters.

The researchers explain that current hologram technology is limited by the materials, which work only in a small region of the electromagnetic spectrum. Recently, researchers have turned to metamaterials, artificially constructed materials with subwavelength structures, to create holograms because they operate over a wider range of frequencies. However, metamaterials are bulky, which means has to travel a long distance through them. Much of the light is absorbed, resulting in low efficiencies for image reconstructions.

Here, the researchers have fabricated a hologram based on a subcategory of metamaterials called metasurfaces, which are 2D and therefore thinner than typical 3D metamaterials. The resulting meta-holograms have the highest efficiency, 18% (defined as the total power of the reconstructed image divided by the power of the incident laser), of any hologram made using to date.

The meta-hologram consists of many tiny gold nanocrosses. Each pixel in the 100 x 100-pixel meta-hologram is constructed with a 6 x 6 array of gold nanorods, and the nanorod pixels of the second image are turned perpendicular to the first, resulting in a 6 x 6 array of gold nanocrosses. Since the length of each nanorod determines the phase of the light waves, the researchers constructed nanorods of four different lengths, yielding 16 combinations, to achieve four phases. The design demonstrates that tuning the geometric parameters of the metasurface allows the phase of the electromagnetic waves to be modulated over a wide frequency range.

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Changing the polarization of the light results in different images appearing and disappearing: NTU is reconstructed using x-polarized light, while RCAS is reconstructed using y-polarized light. Credit: Wei Ting Chen, et al. ©2013 American Chemical Society

"With a wide operation wavelength range, the hologram has high potential as a full-color hologram," coauthor Din Ping Tsai, Director of the Research Center for Applied Sciences at Academia Sinica in Taipei, Taiwan, told Phys.org. Tsai is also a physics professor at National Taiwan University in Taipei, Taiwan.

"The two images are generated by two orthogonal polarizations. Therefore, we simply designed the images of one object with two different viewing angles under the illumination of two orthogonal polarizations. The images will become 3D as the viewer wears conventional polarization 3D glasses. This design increases the amount of information stored in our proposed hologram, since the information can be read out by a pair of perpendicularly polarized incident waves, which is very useful for display and data storage."

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Changing the wavelength of the light results in different colors: red images (640-nm laser), blue images (488-nm laser), or both red and blue images (both lasers). Credit: Wei Ting Chen, et al. ©2013 American Chemical Society

To demonstrate the meta-hologram, the researchers reconstructed the images "NTU" (National Taiwan University in Taipei, Taiwan) and "RCAS" (Research Center for Applied Sciences at Academia Sinica in Taipei, Taiwan), originally taken by a CCD camera under x- and y-polarized light, respectively. They could reconstruct the images using different wavelengths of light, demonstrating the broadband functionality of the meta-hologram. As shown in the videos, the images can be reconstructed individually by controlled the polarization of the lasers. Moreover, the can also be reconstructed by an incoherent light source.

The researchers expect that the efficiency of the meta-hologram can be further improved by using more than four different lengths of nanorods to increase the number of phase levels.

"Our future research plan is to develop a hologram with RGB colors and active phase-controlled devices with a switching frequency that is much larger than that of a spatial light modulator," Tsai said.

More information: Wei Ting Chen, et al. "High-Efficiency Broadband Meta-Hologram with Polarization-Controlled Dual Images." Nano Letters. DOI: 10.1021/nl403811d

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"Meta-hologram produces dual images and multiple colors (w/ Video)." January 9th, 2014. http://phys.org/news/2014-01-meta-hologram-dual-images-multiple-video.html