Artistic illustration of a photonic integrated device. In one arm an incident fundamental waveguide mode (with one lobe in the waveguide cross-section) is converted into the second-order mode (with two lobes in the waveguide cross-section). In the other arm the incident fundamental waveguide mode is converted into strong surface waves. (Illustration courtesy of Adam Overvig and Nanfang Yu)

A team of Columbia Engineering researchers, led by Applied Physics Assistant Professor Nanfang Yu, has invented a method to control light propagating in confined pathways, or waveguides, with high efficiency by using nano-antennas. To demonstrate this technique, they built photonic integrated devices that not only had record-small footprints but were also able to maintain optimal performance over an unprecedented broad wavelength range.

Photonic integrated circuits (ICs) are based on light propagating in optical waveguides, and controlling such light propagation is a central issue in building these chips, which use light instead of electrons to transport data. Yu’s method could lead to faster, more powerful, and more efficient optical chips, which in turn could transform optical communications and optical signal processing.

The optical power of light waves propagating along waveguides is confined within the core of the waveguide: researchers can only access the guided waves via the small evanescent “tails” that exist near the waveguide surface. These elusive guided waves are particularly hard to manipulate and so photonic integrated devices are often large in size, taking up space and thus limiting the device integration density of a chip. Shrinking photonic integrated devices represents a primary challenge researchers aim to overcome, mirroring the historical progression of electronics that follows Moore’s law, that the number of transistors in electronic ICs doubles approximately every two years.

Yu’s team found that the most efficient way to control light in waveguides is to “decorate” the waveguides with optical nano-antennas: these miniature antennas pull light from inside the waveguide core, modify the light’s properties, and release light back into the waveguides. The accumulative effect of a denselypacked array of nano-antennas is so strong that they could achieve functions such as waveguide mode conversion within a propagation distance no more than twice the wavelength.

Yu’s teams created waveguide mode converters that can convert a certain waveguide mode to another waveguide mode; these are key enablers of a technology called “mode-division multiplexing” (MDM). An optical waveguide can support a fundamental waveguide mode and a set of higher-order modes, the same way a guitar string can support one fundamental tone and its harmonics. MDM is a strategy to substantially augment an optical chip’s information processing power: one could use the same color of light but several different waveguide modes to transport several independent channels of information simultaneously, all through the same waveguide.

He plans next to incorporate actively tunable optical materials into the photonic integrated devices to enable active control of light propagating in waveguides. Such active devices will be the basic building blocks of augmented reality (AR) glasses—goggles that first determine the eye aberrations of the wearer and then project aberration-corrected images into the eyes—that he and his Columbia Engineering colleagues, Professors Michal Lipson, Alex Gaeta, Demetri Basov, Jim Hone, and Harish Krishnaswamy are working on now. Yu is also exploring converting waves propagating in waveguides into strong surface waves, which could eventually be used for on-chip chemical and biological sensing.

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