Abstract
Abstract Metallic nanoparticles supporting a localized surface plasmon resonance have emerged as promising platforms for nanoscopic labels, sensors, and (photo-) catalysts. To use nanoparticles in these capacities, and to gain mechanistic insight into the reactivity of inherently heterogeneous nanoparticles, single-particle characterization approaches are needed. Single-particle scattering spectroscopy has become an important, highly sensitive tool for localizing single plasmonic nanoparticles and studying their optical properties, local environment, and reactivity. In this review, we discuss approaches taken for collecting the scattered light from single particles, their advantages and disadvantages, and present some recent applications. We introduce techniques for the excitation and detection of single-particle scattering such as high-angle dark-field excitation, total internal reflection dark-field excitation, scanning near-field microscopy, and interferometric scattering. We also describe methods to achieve polarization-resolved excitation and detection. We then discuss different approaches for scanning, ratiometric, snapshot, and interferometric hyperspectral imaging techniques used to extract spectral information. Finally, we provide a brief overview of specialized setups for in situ measurements of nanoparticles in liquid systems and setups coupled to scanning tip microscopes.
Highlights
The localized surface plasmon resonance (LSPR) is the collective oscillation of free electrons excited by incident light [1, 2]
We introduce techniques for the excitation and detection of single-particle scattering such as highangle dark-field excitation, total internal reflection darkfield excitation, scanning near-field microscopy, and interferometric scattering
As a result of their large scattering crosssections, metal nanoparticles can be readily characterized in a standard dark-field microscope and localized with nanometer precision [35, 36], allowing them to serve as nonbleaching labels for biological samples [37]
Summary
The localized surface plasmon resonance (LSPR) is the collective oscillation of free electrons excited by incident light (see Figure 1A) [1, 2]. The LSPR functions as a nanoantenna [24, 25], focusing the energy of the incident light to a nanoscopic volume, enhancing the catalytic activity [26,27,28], local heating capacity [29], Raman scattering of molecules attached to the surface [30,31,32], and fluorescence of nearby fluorophores [20, 33, 34]. The combination of the ability of the LSPR to efficiently drive reactions, spectrally monitor these reactions, and localize them, has resulted in 30+ years of intensive research into the optical properties of metal nanoparticles, especially those made of gold [38, 39]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
