Nanoengineering student Chawina De-Eknamkul prepares to transfer monolayer tungsten disulfide onto the photonic crystal/nanohole array template. Photo: Liezel Labios/UC San Diego Jacobs School of Engineering.Engineers at the University of California (UC) San Diego have developed the thinnest optical device in the world – a waveguide that is three layers of atoms thin.
This work is a proof-of-concept for scaling down optical devices to sizes that are orders of magnitude smaller than today's devices. It could lead to the development of higher density, higher capacity photonic chips. The researchers report their findings in a paper in Nature Nanotechnology.
"Fundamentally, we demonstrate the ultimate limit for how thin an optical waveguide can be built," said senior author Ertugrul Cubukcu, a professor of nanoengineering and electrical engineering at UC San Diego.
The new waveguide measures about six angstroms thin – that is more than 10,000 times thinner than a typical optical fiber and about 500 times thinner than on-chip optical waveguides in integrated photonic circuits. It consists of a tungsten disulfide monolayer (made up of one layer of tungsten atoms sandwiched between two layers of sulfur atoms) suspended on a silicon frame. The monolayer is also patterned with an array of nanosized holes to form a photonic crystal.
What's special about this monolayer crystal is that it supports electron-hole pairs, known as excitons, at room temperature. These excitons generate a strong optical response, giving the crystal a refractive index about four times greater than that of air, which surrounds its surfaces. Another material with the same thickness but without the excitons would not have a refractive index as high.
When light is sent through the crystal, it becomes trapped inside and guided along the plane by total internal reflection. This is the basic mechanism for how an optical waveguide works.
Another special feature is that the waveguide can channel light in the visible spectrum. "This is challenging to do in a material this thin," Cubukcu said. "Waveguiding has previously been demonstrated with graphene, which is also atomically thin, but at infrared wavelengths. We've demonstrated for the first time waveguiding in the visible region."
Nanosized holes etched into the crystal allow some light to scatter perpendicular to the plane, so that it can be observed and probed. This array of holes produces a periodic structure that makes the crystal double as a resonator as well.
"This also makes it the thinnest optical resonator for visible light ever to be demonstrated experimentally," said first author Xingwang Zhang, who worked on this project as a postdoctoral researcher in Cubukcu's lab at UC San Diego. "This system does not only resonantly enhance the light-matter interaction, but also serves as a second-order grating coupler to couple the light into the optical waveguide."
The researchers used advanced micro- and nanofabrication techniques to create the waveguide. Creating the structure was particularly challenging, said Chawina De-Eknamkul, a nanoengineering PhD student at UC San Diego and a co-author of the study. "The material is atomically thin, so we had to devise a process to suspend it on a silicon frame and pattern it precisely without breaking it," she said.
This process starts with a thin silicon nitride membrane supported by a silicon frame, which is the substrate upon which the waveguide is built. An array of nanosized holes is patterned into the membrane to create a template. Next, a monolayer of tungsten disulfide crystal is stamped onto the membrane and ions are sent through to etch the same pattern of holes into the crystal.
In the last step, the silicon nitride membrane is gently etched away, leaving the crystal suspended on the silicon frame. The result is an optical waveguide in which the core consists of a monolayer tungsten disulfide photonic crystal surrounded by a material (air) with a lower refractive index.
Moving forward, the team will continue to explore the fundamental properties and physics pertaining to the waveguide.
This story is adapted from material from the University of California, San Diego, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.