Silicon Nanoparticles Trained to Juggle Light


Non-linear antennas

Electromagnetic waves of a wide spectral range are used to transmit information—including radio waves that carry signals over the air, infrared radiation and visible light used in telecommunications and data transmission through fibre optics. An essential component of any equipment that relies on electromagnetic waves for information transmission and processing is the antenna, which is designed to either receive or transmit signals in a particular direction. It is often the case that incoming signals need to be flexibly processed. This requires the use of a reconfigurable antenna, i.e. one whose characteristics (e.g. its radiation pattern) can be changed in a specific manner during signal processing. One possible solution relies on the use of a non-linear antenna, which can be switched by theincident light itself.

Denis Baranov, a Ph.D. student at MIPT and one of the authors of the study, comments on the research findings: "It is a top priority—and at the same time a major challenge—to develop such tuneable antennas operating at infrared and optical frequencies. Nowadays, we can already transmit information through fibre optics at incredible speeds up to hundreds of Gbit/s. However, silicon-based electronics are unable to process the incoming data at that rate. Non-linear nanoantennas that work at optical wavelengths could help us to resolve this problem and make ultrafast, all-optical signal processing possible."

Silicon nanoparticles

To demonstrate non-linear switching, the authors of a paper published in ACS Photonics have studied a dielectric nanoantenna—an optically resonant spherical nanoparticle made of silicon. While spherical particles of all sizes show resonances, it is the size of the particle that determines its resonant wavelength. The first of these resonances, which can be observed at the longest wavelength, is the magnetic dipole resonance. Incident light of a certain wavelength induces a circular electric current in the particle, similar to the current that flows in a closed circuit. Because silicon has a high refractive index, particles with diameters approaching 100 nm will already show the magnetic dipole resonance at optical frequencies, making them useful for enhancing various optical effects at the nanoscale. The team had already used silicon nanosphere resonances to enhance Raman scattering in an earlier study.

The optical properties of a non-linear silicon nanoantenna are manipulated by means of electron plasma generation. As silicon is a semiconductor, there are almost no electrons in its conduction band under normal conditions. However, exposing it to a laser pulse of high intensity and very short duration excites the electrons into the conduction band. This significantly alters the properties of the material as well as the behaviour of the silicon nanoantenna itself, causing it to scatter light in the direction of the incident pulse. Thus, by exposing a particle to a short and intense pulse, its behaviour as an antenna can be dynamically controlled.

In order to demonstrate ultrafast nanoantenna switching, the authors of the study carried out a series of experiments, which involved the irradiation of an array of silicon nanoparticles with a short and intense laser pulse and a continuous measurement of their transmittance. The researchers observed that the transmission coefficient of a structure changed by several percent within 100 femtoseconds and then gradually returned to its initial value.

On the basis of the experimental results, the researchers developed an analytical model that describes the ultrafast non-linear dynamics of the nanoantenna examined in the study, as well as the generation and relaxation of electron plasma in silicon. According to the model, a radical change in the scattering diagram of the antenna occurs within a very short period of time—on the order of 100 femtoseconds. Before the pulse arrival, the amount of energy scattered by the particle in the forward direction is nearly the same as in the backward direction. However, driven by a short pulse, the antenna switches to almost perfectly unidirectional forward-scattering. Theoretical predictions backed by the experimental data suggest that an antenna of this kind would have a bandwidth of about 250 Gbit/s, whereas conventional silicon-based electronics rely on components with bandwidths limited to only tens of Gbit/s.

"The research shows that silicon nanoparticles might well become the basis for developing ultrafast optical nanodevices. Our model can be used to design nanostructures containing silicon particles that are more complex, which would enable us to manipulate light in a most unusual way. For example, we hope to eventually control not just the amplitude of an optical signal, but also its direction. We expect to be able to 'turn' it by a specified angle on an ultrafast timescale," says Sergey Makarov, a senior researcher at the Department (Chair) of Nanophotonics and Metamaterials of the ITMO University.