Trajectory-Profile-Guided Single Molecule Tracking for Assignment of One-Dimensional Diffusion Trajectories

Abstract: A variety of algorithms exist for optical single molecule tracking in two and three dimensions. One general class of algorithms employs cost-functionals to link the individual fluorescent spots, produced by a molecule in sequential video frames, into trajectories. This method has also been used to track one-dimensional (1D) molecular motions for relatively low diffusion rates (i.e., D < 1 μm(2)/s). At high diffusion rates, the cost-functional approach often fails to accurately reproduce 1D trajectories, partic… Show more

“…Local, nanoscale differences in concentrations based on heterogeneous pore size, surface chemistry, and confinement effects drive the function of separation materials. Single-molecule tracking of diffusion and localization of adsorption in separation materials has characterized local differences in one and two dimensions, ,,, but chromatography columns and membranes are three-dimensional on larger scales: chromatographic beads with diameters of one to tens of μm or polymeric membranes that are ∼100 μm thick.…”

Transforming Separation Science with Single-Molecule Methods

“…Local, nanoscale differences in concentrations based on heterogeneous pore size, surface chemistry, and confinement effects drive the function of separation materials. Single-molecule tracking of diffusion and localization of adsorption in separation materials has characterized local differences in one and two dimensions, ,,, but chromatography columns and membranes are three-dimensional on larger scales: chromatographic beads with diameters of one to tens of μm or polymeric membranes that are ∼100 μm thick.…”

Transforming Separation Science with Single-Molecule Methods

“…The aim of this review article is to summarize the latest developments in the optical super-resolution imaging of catalytic reactions; however, as a powerful tool in the field of nanoscience, the application of optical super-resolution imaging is not limited to only the subjects mentioned above. Many other systems have also been studied, such as energy migration processes in conjugated polymers, − J-aggregates, and perovskite nanocrystals; mapping of nanostructures; − molecular diffusion and transport processes in porous materials; − imaging of quantum dots; , dynamics of polymers; − detection of the quenching centers of graphene, and probing of plasmonic hot spots in metal nanoparticles. − …”

Optical Super-Resolution Imaging of Surface Reactions

“…Single molecules can routinely be located to within ±20-50 nm, but the precision may approach ±1 nm in some situations (49,50). Finally, existing methods may be used to link the spot locations into trajectories (Figure 4d anisotropic single-molecule motions in nanostructured materials continue to be developed (51). The trajectories obtained reflect the time-dependent translational motions of the molecules, as modulated by confinement, partitioning, or adsorption phenomena.…”

Single-Molecule Investigations of Morphology and Mass Transport Dynamics in Nanostructured Materials