A variety of
nanoplasmonic waveguides of complex shapes
Waveguides that
combine metallic and semiconductor structures can be made more compact
Increasing the areal density at which electronic
components can be integrated onto a computer chip has always been key to the
revolution of technological applications. However, achieving the same feat in
the world of optics has been proven difficult as light waves cannot be
compressed to sizes below their wavelength by conventional semiconductor-based
opticalwaveguides.
Metallic structures, in theory, are able to provide such
functionality through so-called plasmonic effects. In practice, however, the
large optical losses have hampered the implementation of such schemes.
Combining the benefits of conventional optics with plasmonics, Shiyang Zhu and
co-workers at the A*STAR Institute of Microelectronics have now demonstrated
how structures made of semiconductor and metals represent a more viable
approach to effectively miniaturize optical circuits1.
Plasmonic effects are based on motions of electrons at
the surface of metals that act like an antenna on incoming light. They can be
very effective to squeeze light into small volumes, although transport losses
when guiding light along such small volumes are much higher than for
conventional semiconductor waveguides.
Zhu and colleagues observed waveguides based on semiconductor
silicon. First, ridges are etched out of silicon chip to form the basis for the
waveguide architecture. The surface of the silicon is then oxidized to provide
electrical insulation of the silicon before it is covered in a thin copper
layer (see image).
This architecture has the benefit of very efficiently
squeezing light into the waveguide via the surrounding copper layer, but
travels mostly along the core made of silicon and not the metal. Silicon is
transparent for light at telecommunications frequencies and thus shows low
losses. ”These waveguide structures are not only compatible with the
fabrication processes of silicon computer chips,” says Zhu. “More importantly,
the use of silicon and silicon oxide and related semiconductors enables further
possibilities to potentially achieve other effects, such as light
amplification, and control over the plasmon properties.”
Having previously shown that such waveguides are able to
guide light efficiently, the researchers have now demonstrated a number of
complex photonic structures, including the splitting of light beams at multiple
junctions, the propagation of light across multiple kinks and steps, resonator
structures that show light interference effects and many more.
“This is only a first step towards the varied and complex
effects possible with these structures,” says Zhu. “The next step is to
demonstrate some of the active functionality, especially to combine waveguides
with ultracompact plasmonic light modulators based on related designs for complete
functional nanoplasmonic circuits.”
The A*STAR-affiliated researchers contributing to this
research are from the Institute of
Microelectronics
References
- Zhu,
S., Lo, G. Q. & Kwong, D. L. Components for silicon plasmonic
nanocircuits based on horizontal Cu-SiO2-Si-SiO2-Cu
nanoplasmonic waveguides. Optics Express 20,
5867–5881 (2012). | article
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