Spatially shaping waves to penetrate deep inside a forbidden gap

TL;DR

This paper demonstrates a method to send waves deeper into photonic crystals by spatially shaping wavefronts, overcoming the natural Bragg reflection limit, and exploiting transport channels caused by fabrication deviations.

Contribution

It introduces a wavefront shaping technique to penetrate deeper into forbidden gaps in photonic crystals, leveraging disorder-induced transport channels.

Findings

Enhanced internal wave intensity up to 100 times with wavefront shaping

Extended wave penetration up to 8 times the Bragg length

Utilized fabrication deviations to induce transport channels

Abstract

It is well known that waves incident upon a crystal are transported only over a limited distance - the Bragg length - before being reflected by Bragg interference. Here, we demonstrate how to send waves much deeper into crystals, by studying light in exemplary two-dimensional silicon photonic crystals. By spatially shaping the optical wavefronts, we observe that the intensity of laterally scattered light, that probes the internal energy density, is enhanced at a tunable distance away from the front surface. The intensity is up to $100 \times$ enhanced compared to random wavefronts and extends as far as $8 \times$ the Bragg length. Our novel steering of waves inside a forbidden gap exploits the transport channels induced by unavoidable deviations from perfect periodicity, here unavoidable fabrication deviations.