Understanding inhomogeneous crystallization dynamics of phase-change materials in the vicinity of metallic nanoantennas

TL;DR

This study investigates how metallic nanoantennas influence the inhomogeneous crystallization of phase-change materials, combining experiments and multiphysics modeling to optimize local resonance tuning for advanced metasurface applications.

Contribution

It provides the first detailed experimental and theoretical analysis of inhomogeneous PCM crystallization near metallic nanoantennas, enabling precise control of metasurface resonances.

Findings

Inhomogeneous crystallization caused by metallic nanoantennas was observed.

A multiphysics model successfully simulated the crystallization process.

Optimized laser parameters and antenna geometry improve crystallization control.

Abstract

Optical metasurfaces composed of metallic or dielectric scatterers (meta-atoms) promise a powerful way of tailoring light-matter interactions. Phase-change materials (PCMs) are prime candidates for non-volatile resonance tuning of metasurfaces based on a refractive index change. Precise resonance control can be achieved by locally applying laser pulses to crystallize a PCM, modifying the dielectric surrounding of meta-atoms. However, the complex crystallization kinetics of PCMs in the vicinity of metallic meta-atoms have not been studied yet. Here, we experimentally investigate metallic dimer antennas on top of the PCM Ge3Sb2Te6 and address these nanoantennas with laser pulses. Our study reveals inhomogeneous crystallization caused by the absorption and heat conduction of the metallic nanoantennas. A self-consistent multiphysics model, including electromagnetic, thermal, and phase-transition processes, is employed to simulate the crystallization and understand the resulting resonance shift of the antennas. This model enables the optimization of the laser parameters and the geometry of the meta-atoms to achieve an optimal crystallization pattern and resonance shift. Our work paves the way towards complex antenna geometries optimized for local addressing of PCMs to achieve sophisticated crystallization patterns, enabling on-demand programming of individual nanoantennas within metasurfaces.