Single-molecule fluorescent microscopy (SMFM) has proved to be a powerful imaging tool
for in situ monitoring catalytic reactions on individual nanocatalysts with high spatiotemporal …

Single‐molecule fluorescence microscopy (SMFM) has been considered as a powerful tool
to study nanocatalysis of single nanoparticles, due to its single‐molecule sensitivity and high …

This tutorial review covers recent developments in using single-molecule fluorescence
microscopy to study nanoscale catalysis. The single-molecule approach enables following …

Real-time dynamic imaging of the electrochemical reactions on individual nanoparticles is
important for the design of novel and highly efficient electrocatalytic systems. Single …

Single-molecule fluorescence microscopy enables the direct observation of individual
reaction events at the surface of a catalyst. It has become a powerful tool to image in real …

Due to the synergistic effect, heterostructure-based nanocatalysts usually possess higher
catalytic performance; therefore, much attention has been attracted in this filed. To …

The electrochemical interface is an ultrathin interfacial region between the electrode and
solution where electrochemical reactions occur. The study of the electrochemical interface …

Nanoscale catalysts are important for electrocatalysis, especially in energy conversion as in
photoelectrochemical cells and fuel cells. Understanding their reactivity is essential for …

In recent years, single-molecule and single-particle fluorescence microscopy has emerged
as a tool to investigate chemical systems. After an initial lag of over a decade with respect to …

Electrogenerated chemiluminescence microscopy (ECLM) provides a real-time imaging
approach to visualize the surface-dependent catalytic activity of nanocatalysts, which helps …