Light-assisted, templated self assembly using a photonic-crystal slab

TL;DR

This paper introduces a novel light-assisted, templated self-assembly method using photonic-crystal slabs to create stable, symmetry-controlled particle patterns, expanding the possibilities for nanofabrication and device customization.

Contribution

The authors demonstrate for the first time a technique that uses guided-resonance modes in photonic crystals to direct self-assembly into non-traditional symmetries.

Findings

Successfully created stable, periodic particle patterns using optical potentials.

Achieved control over particle cluster symmetry matching the photonic crystal lattice.

Potential applications in nanofabrication and optical device engineering.

Abstract

The process of self-assembly is guided by the minimization of free energy, which limits the symmetries available for assembly and ultimately the usefulness of devices fabricated in this fashion. Here, we demonstrate experimentally for the first time a technique which we term light-assisted, templated self assembly. By exciting a guided-resonance mode of a photonic-crystal slab, an optical potential landscape is created above the slab which results in stably trapped, periodic patterns of particles at the potential minima. The underlying symmetry of particle clusters matches that of the photonic-crystal lattice, thus enabling square, rectangular or other symmetries not usually available for assembly due to energy concerns. We anticipate that this technique could be used to tailor the optical characteristics of nanofabricated devices, and the optical trapping techniques demonstrated herein may enable a variety of complex nanomanipulation tools and lab-on-a-chip devices.