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Light waveguide for faster electronics

Light waveguide for faster electronics

Technology News |
By Wisse Hettinga



Because processing information with light can be more efficient than with electrons used in current devices, there is good reason to confine light onto a chip. But light and the bits of information it carries tend to leak and scatter out of the tiny components that must fit on a chip.

The novel cladding, or waveguide, developed by the researchers prevents such information leaks – particularly around sharp bends where light bounces off track and scatters, resulting in lost or scrambled information. Preventing this could facilitate the integration of photonic with electric circuitry, increasing communication speed and reducing power consumption.

“We want the bits of information that we are sending in the waveguide to travel along tight bends and simultaneously not be lost as heat. This is a challenge,” said Zubin Jacob, Purdue assistant professor of electrical and computer engineering.

What makes the waveguide cladding so unique is anisotropy, meaning that the cladding design enables light to travel at different velocities in different directions. By controlling the anisotropy of the cladding, the researchers prevented light from leaking off track into other waveguides where “crosstalk,” or mixing, of information would occur. Instead, bits of information carried by light bounce off by “total internal reflection” and stay strongly confined within a waveguide.

An anisotropic metamaterial waveguide cladding keeps light travel on track throughout a computer chip, preventing leaked and jumbled bits of information. Image courtesy of Purdue University, Saman Jahani.

“The waveguide we made is an extreme skin-depth structure, which means that any leakage that does happen will be really small,” said Saman Jahani, Purdue graduate research assistant in electrical and computer engineering. “This approach can pave the way for dense photonic integration on a computer chip without worrying about light leakage.”

This work was performed by an international team of researchers at Purdue University, University of Alberta, Texas Tech University, the University of British Columbia and the Shanghai Institute of Microsystem and Information Technology. The team’s findings appear in the journal Nature Communications.

 

Paper

Controlling evanescent waves using silicon photonic all-dielectric metamaterials for dense integration

Saman Jahani [1] [2], Sangsik Kim [2] [3], Jonathan Atkinson [1], Justin C. Wirth [2], Farid Kalhor [1] [2], Abdullah Al Noman [2], Ward D. Newman [1] [2], Prashant Shekhar[1], Kyunghun Han [2], Vien Van [1], Raymond G. DeCorby [1], Lukas Chrostowski [4], Minghao Qi [2] [5] and Zubin Jacob [1] [2].

[1] University of Alberta, Demonton, Canada
[2] Purdue University, West Lafayette, IN, USA
[3] Texas Tech University, Lubbock, TX, USA
[4] University of British Columbia, Vancouver, Canada
[5] Chinese Academy of Sciences, Shanghai, China

Article reference: https://dx.doi.org/10.1038/s41467-018-04276-8

www.purdue.edu

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