Co-assembly of Block Copolymers and Cobalt Ferrite Nanoparticles for Magnetic Material Design.

Abstract

Hybrid materials that integrate photonic and magnetic functionalities are a major focus of next-generation nanotechnology, but their scalable production remains a significant challenge. Here, we present a facile strategy to produce hybrid photonic microparticles by coassembling poly-(styrene)-b-poly-(2-vinylpyridine) (PS-P2VP) block copolymers with 10 nm cobalt ferrite nanoparticles within emulsion droplets. This method allows the formation of highly ordered, hierarchical, onion-like structures with alternating concentric layers. Selective localization of the nanoparticles within P2VP domains preserves the periodicity essential for structural coloration while introducing tunable magnetic properties. Optical characterization confirms that the microparticles exhibit a vivid blue structural color and maintain a well-defined photonic bandgap up to a critical nanoparticle concentration, after which the structural order is disrupted. Remarkably, the nanostructure order of the polymer matrix induces a partial alignment of the magnetic easy axis of the nanoparticles, increasing the thermal stability of the magnetization (i.e., increase in the reduced remanent magnetization). This distinctive synergy between photonic and magnetic properties establishes a platform for multifunctional materials with potential applications in magnetically tunable photonic devices, advanced sensors, and responsive materials. The results demonstrate a scalable and versatile approach to fusing photonic architectures with functional nanomaterials, providing design opportunities for next-generation hybrid materials.