Physicists Design New Nanoresonators With Giant Nonlinear Response

An international research team has found a way to make frequency conversion of light at the nanoscale a hundred times more efficient. The new method is based on isolated dielectric nanoparticles supporting the so-called bound states in the continuum. Such states appear when radiating fields in the particle suppress each other, so that the electromagnetic energy inside the particle can be trapped. This prediction can be employed for a new generation of tiny frequency conversion devices, nanolasers. The research was published in Physical Review Letters on July 19, 2018 as a cover story.

One of the key problems of nonlinear nanophotonics is the frequency conversion of electromagnetic radiation at the nanoscale. By changing the frequency, the radiation can be converted from one spectral band to another: from terahertz to infrared, and from infrared to visible. This transformation can be carried out effectively by macroscopic devices, but it is a challenge to achieve the frequency conversion at the nanoscale.

The reason is that the interaction of nanoparticles with light is quite special because of their very small size. Therefore, in order to increase efficiency of the frequency conversion of light at the nanoscale, it is necessary to reduce energy losses during the key processes occurring in the nanoparticle: radiation input, energy confinement, and nonlinear conversion.

To solve all these problems, an international team of physicists from ITMO University, Nonlinear Physics Centre of the Australian National University, and the University of Brescia in Italy proposed to exploit a new type of nanoscale resonators. They are, in essence, disk-shaped dielectric nanoparticles with high refractive index that support the so-called bound states in the continuum. Such states can be created when several types of electromagnetic energy oscillations in the particle mutually suppress each other. In this way, the energy of light can be "locked" inside the particle.

Mathematically, the energy can be locked forever provided that resonators are absolutely ideal. In practice, it is possible to trap light for a finite, yet quite a long time, even in a single nanoparticle. This requires an optimal ratio of the particle shape, size, and material.

Kirill Koshelev
Kirill Koshelev

"Although we described such peculiar dielectric nanoresonators previously, we have not yet analysed their practical perspectives. Now, together with our Italian colleagues Dr Luca Carletti and Prof Constantino De Angelis, we calculated how this resonator generates the light with a double frequency. The results show that this structure helps to increase the efficiency of the nonlinear processes by two orders of magnitude. However, this was not that easy, as we had to find the optimal way of pumping the energy into the resonator. We found out that in our case the incident wave had to be polarized in a way that it oscillates along the tangent to the circle. This coincides with the structure of the electromagnetic field inside the particle," says Kirill Koshelev, a member of the International Metamaterial Laboratory of  ITMO University.

As a result, the research team managed to achieve a record-high efficiency of frequency doubling of light by dielectric nanoparticles. Now, instead of a hundredth part of a percent, it is possible to save several percent of light energy during the conversion. This result paves the way towards experimental detection of radiation converted by a nanoparticle, which means that the proposed method can be used in practical applications.

"We have suggested a design of nanoscale converters of light which can be used for various applications. For example, they can be used in night vision flat-optics devices which convert infrared radiation into visible light. At the same time, the dielectric material we chose, aluminium-gallium arsenide, has the mature fabrication technology. Since the material is widely available, we expect that our idea and predictions will push the further progress in nonlinear nanophotonics and meta-optics," adds Professor Yuri Kivshar, co-Chair of the Department of Nanophotonics and Metamaterials of  ITMO University also Distinguished Professor of the Australian National University.

The research was financially supported by the Russian Science Foundation (grant №17-12-01581).

Reference: Giant nonlinear response at the nanoscale driven by bound states in the continuum. Luca Carletti, Kirill Koshelev, Costantino De Angelis, Yuri Kivshar. Physical Review Letters, 19 July, 2018.

Scientific Communications Office
Personalities
  • Yuri Kivshar

    Head of Nonlinear Physics Centre of the Australian National University (ANU) (Canberra, Australia) and ITMO's International Research Centre for Nanophotonics and Metamaterials

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