Confined nanoscale sound controls light in a microresonator

Researchers demonstrate a semiconductor device for the tailored generation of Brillouin signals in the ultrahigh 100GHz-THz regime.

Scanning electron micrograph of the novel Brillouin scattering micropillar device

Figure: Scanning electron micrograph of the novel Brillouin scattering micropillar device. The diameter is 4.5 micrometers. The false colors mark the inner part confining high frequency vibrations (in orange) and the outer part confining light (in blue).


July 4, 2019

When traversing a solid material such as glass, a light wave can deposit part of its energy in a mechanical wave, leading to a color change of the light. This process called “Brillouin scattering” has important technical applications. Long-range optical data transmission on the internet, for example, relies on amplifiers generating mechanical waves in an optical fiber via a strong laser light field. The frequencies at which mechanical waves can be optically excited, and hence the optical spectra that can be generated through Brillouin scattering, are usually dictated by the material properties. So far, this has limited the range of possible applications.

Researchers from the Centre de Nanosciences et de Nanotechnologies - C2N (CNRS/Université Paris-Saclay) have recently demonstrated a micropillar made from alternating layers of two different semiconductor materials that constitutes a novel device to control light with sound. The micropillar device can shape an optical spectrum through Brillouin scattering almost completely at will. Their work1 was published in the journal Optica.

The main trick behind the device’s versatility is to control light and sound by separate parts of the device. In the state-of-the-art technology facility of the C2N, the researchers fabricated micropillars in which the inner layers, with extremely fine thicknesses in the range of a few nanometers, constitute a resonator for sound waves at particularly high frequencies of 300GHz. This resonator is embedded between thicker layers, which resonantly confine light. Since light and sound are confined in the same spatial region in all three dimensions of space, the device is also unusually efficient in Brillouin scattering generation in comparison to its size.

In their study, the researchers devise a novel optical technique to detect and optimize the generated Brillouin spectra under the influence of thermal effects. They are, however, sure that the impact of their discovery goes well beyond that: Micropillar resonators can be directly interfaced with optical fibers. Therefore, they are a promising platform to integrate Brillouin light sources with optical nano-circuitry on a chip. The researchers also point out that their device may be combined with active lasing media and could even be improved to reach the regime of active acoustics, that is, the mechanical wave analog of a laser.

1 The research was funded in part by the ERC, the French ANR, the French Network of nanofabrication facilities RENATECH and the German Research Foundation DFG.

Brillouin Scattering in Hybrid Optophononic Bragg Micropillar Resonators at 300 GHz,
M. Esmann1, F. R. Lamberti1, A. Harouri1, L. Lanco1, I. Sagnes1, I. Favero2, G. Aubin1, C. Gomez-Carbonell1, A. Lemaître1, O. Krebs1, P. Senellart1 and N. D. Lanzillotti-Kimura1
Optica - Vol. 6, Issue 7, pp. 854-859 (2019)
DOI: https://doi.org/10.1364/OPTICA.6.000854

1 Centre de Nanosciences et de Nanotechnologies (CNRS, Université Paris-Saclay)
2 Matériaux et Phénomènes Quantiques (CNRS Université de Paris)