6 August 2019

[Nanotechnology] – Nanoantennas to improve ultra-fast wireless connections

Home > News > [Nanotechnology] – Nanoantennas to improve ultra-fast wireless connections
Flèche contenu
New Si Nano Antena - Codex International

This type of configuration opens the door to the development of new miniature nanobiosensors and to the design of future systems and networks based on quantum optics. The work of the UPV researchers has been published in the ACS Photonics journal.
The results of the research conducted by the NTC-UPV team combine the benefits of dielectric wireless applications and the benefits of plasmonics. This opens the path to a new generation of ultra-integrated hybrid networks, which is the main contribution of the research.
“We experimentally proved the first wireless dielectric-plasmonic connection thanks to a new type of dielectric nanoantenna that overcomes the limitations of plasmonics, opening the door to new hybrid configurations. The results we have obtained have a direct implication in the design of reconfigurable communication networks inside the chip, in the development of ultra-fast optic devices, and in the practical implementation of ultra-compact biosensors. Thanks to plasmonic structures, this also opens the door to the creation of interfaces with future quantum systems,” says Javier Martí, head of the Nanophotonic Technology Centre of the UPV.
More efficient
Sergio Lechago, researcher at the NTC and co-author of the study, explains that plasmonic devices have enabled the development of important applications in fields such as spectroscopy, near-field and sensing optic microscopy, thanks to their unique capability of manipulating light on a nano level.
Within the communications integrated in the chip, plasmonics enable the development of ultra-compact and affordable devices (modulators, detectors or sources) that can function at very high operation speeds with low energy consumption. “The natural way of interconnecting these devices in the optic chip is by using metallic nanoguides. However, guiding light through these devices leads to very high propagation losses and entails certain restrictions regarding reconfigurability,” explains Carlos García Meca, from the NTC and fellow co-author of the study.
“The use of plasmonic nanoantennas has been proposed to replace and improve the performance of guided metallic interconnections, but these antennas have low directivity and high losses which hinder their use in many practical applications. In this work, we overcame all these limitations by introducing a new dielectric nanoantenna design that acts as an efficient interface for plasmonic systems. This makes it possible to combine the benefits of plasmonics with those of silicon photonics, which can lead to more efficient, fast and reconfigurable chips,” adds García Meca.
This new breakthrough developed in the laboratories of the Centre of Nanophotonic Technology of the UPV could also be applied to fields such as biochemical or agri-food industries, thanks to the role that these hybrid systems can carry out as sensors with multiple purposes, allowing the interaction of light with nanoscopic organic and inorganic structures.

Discover Also
[Nanophotonics] – Silver sawtooth creates valley-coherent light for nanophotonics 23 February 2020

Scientists at the University of Groningen used a silver sawtooth nanoslit array to produce valley-coherent photoluminescence in two-dimensional tungsten disulfide flakes at room temperature.
Until now, this could only be achieved at very low temperatures. Coherent light can be used to store or transfer information in quantum electronics. This plasmon-exciton hybrid device is promising for use in integrated nanophotonics (light-based electronics).

Read more
[Thin Films] – Nanoparticle Decoration of Carbon Nanotubes by Sputtering 11 August 2019

Carbon nanotubes (CNTs) that have been decorated with nanoparticles are effective biological and chemical sensors, photovoltaics, electronic conformal thermal interface substances, and surfaces for heterogeneous catalysis. The particle structure of the sidewalls of the CNT has an effect on the performance and properties of metal-nanotube hybrids for these types of applications.

Read more