Harmonizing Plasmonic and Photonic Effects to Boost Photocatalytic H2 Production over 550 mmol ⋅ h−1 ⋅ gcat−1

Plasmonic photonic crystal enables efficient hydrogen evolution from water by harmonizing competing photonic and plasmonic effects to effectively trap and concentrate light onto plasmonic catalysts. This design demonstrates a remarkable H₂ evolution at 560 mmol ⋅ h⁻¹ ⋅ g_Ag ⁻¹, surpassing bare plasmonic catalyst by >10⁶-fold and other emerging high-performance photocatalytic designs by 280-fold.

Abstract

Integrating plasmonic nanoparticles with photonic crystals holds immense potential to enhance green hydrogen photosynthesis by amplifying localized electromagnetic field through generating surface plasmons and slow photons. Current plasmonic photonic designs primarily employ semiconductor-based structural backbone deposited with plasmonic nanoparticles. However, the competition between various optical phenomena in these ensembles hinders effective field enhancement rather than facilitating it. This limitation creates a formidable performance bottleneck that retards hydrogen evolution. Herein, we enhance plasmonic catalysis for efficient hydrogen evolution by effectively harmonizing plasmonic and photonic effects. This is achieved by using inert SiO₂ opal as a non-photoabsorbing photonic framework. By aligning the excitation wavelengths of surface plasmons and slow photons, our optimized plasmonic photonic crystals demonstrates a remarkable H₂ evolution rate of 560 mmol h⁻¹ g_Ag ⁻¹, surpassing bare plasmonic Ag nanoparticles by >10⁶-fold and other high-performance photocatalytic designs by 280-fold. Mechanistic studies highlight the pivotal role of the non-photoabsorbing photonic backbone in facilitating effective light confinement through the photonic effect. This in turn boosts the plasmonic field for enhanced photocatalytic H₂ evolution, even without needing additional co-catalysts. Our work offers valuable insights for future design of electromagnetically hot plasmonic catalysts to achieve efficient light-to-chemical transformations in diverse energy, chemical, and environmental applications.

Zum Volltext