Phase behavior of thermoresponsive colloids drives re-entrant plasmon coupling

TL;DR

This study reveals a re-entrant plasmon coupling behavior in thermoresponsive colloids, driven by colloidal stability and NP loading, enabling programmable optical properties in soft plasmonic systems.

Contribution

It uncovers the counter-intuitive re-entrant plasmon coupling behavior and links colloidal stability to optical response in thermoresponsive microgel-NP complexes.

Findings

Plasmon coupling initially increases then decreases with NP loading.

Colloidal stability influences whether coupling is governed by interparticle distance or aggregation.

A phase diagram relates colloidal stability to optical response.

Abstract

Plasmonic nanoparticles (NPs) integrated within thermoresponsive polymeric microgels provide a versatile platform for the realization of stimuli-responsive optical materials, where the microgel volume phase transition enables dynamic control of plasmon coupling. This study uncovers a counter-intuitive re-entrant behavior with increasing NP loading in which plasmon coupling initially strengthens and subsequently weakens beyond a critical NP-to-microgel number ratio. By combining light and X-ray scattering techniques with optical spectroscopy and electrophoretic mobility measurements, it is demonstrated that plasmon coupling is governed not only by the interparticle distance between NPs confined within individual microgels, but also by the colloidal stability of the hybrid complexes. At intermediate NP loadings, surface charge inhomogeneities induced by NP adsorption promote aggregation of microgel-NPs complexes, resulting in enhanced plasmon coupling. In contrast, when the complexes remain colloidally stable, coupling is dictated solely by NP organization within the corona of individual microgels. A quantitative relationship between plasmon coupling and interparticle distance reveals two distinct coupling regimes. This behavior is rationalized through a phase diagram linking colloidal stability to optical response. These findings identify colloidal stability as a key parameter for designing soft plasmonic systems with programmable optical properties.