AI Article Synopsis
- Researchers developed a post-synthesis etching method to modify the porosity of FeO shells on silver nanoparticles (Ag NPs), which enhances their chemical and optical properties.
- Increased shell porosity leads to improved catalytic activity and a stronger surface-enhanced Raman spectroscopy (SERS) effect, resulting from better chemical diffusion into the Ag core.
- The new 1D and 2D magnetoplasmonic arrays created from these nanoparticles display unique plasmon properties, and their coloration can be adjusted by altering porosity or adding metal layers, paving the way for advanced catalysts, optical filters, and sensing technologies.
Article Abstract
Control of the chemical and physical properties of nanoscale colloids and their nanoassemblies remains a challenging issue for enhancing the performance and functionalities of nanodevices. In this study, we report a post-synthesis etching method to tailor the porosity of the FeO shells coating on Ag NPs, establishing a facile but effective approach to regulate the chemical and optical properties of the colloids and their assembled structures. As the shell porosity increases, the NPs are transformed, producing enhanced catalytic activity and the surface-enhanced Raman spectroscopy (SERS) effect, which results from enhanced chemical diffusion into the Ag core. Magnetoplasmonic (MagPlas) one- (1D) and two- (2D) dimensional arrays fabricated using these porosity-controllable NPs exhibit intriguing plasmon properties that are strongly affected by the porosity of the particle shell. Furthermore, the bright coloration of the 2D arrays is tuned by changing the shell porosity or introducing an additional metallic layer. Such 1D and 2D porous MagPlas metastructures possessing FeO shells with tunable porosities are a fulcrum for developing recyclable catalysts and tunable optical filters with optimized activity, selectivity, and sensitivity, as well as color displays and sensing platforms.
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| http://dx.doi.org/10.1039/d0nr01178a | DOI Listing |
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