Nanoparticle movement: Plasmonic forces and physical constraints

Nanoparticle structures observed in aberration-corrected electron microscopes exhibit many types of behavior, some of which are dominated by intrinsic conditions, unrelated to the microscope environment. Some behaviors are clearly driven by the electron beam, however, and the question arises as to whether these are similar to intrinsic mechanisms, useful for understanding nanoscale behavior, or whether they should be regarded as unwanted modification of as-built specimens. We have studied a particular kind of beam–specimen interaction – plasmon dielectric forces caused by the electric fields imposed by a passing swift electron – identifying four types of forced motion, including both attractive and repulsive forces on single nanoparticles, and coalescent and non-coalescent forces in groups of two or more nanoparticles. We suggest that these forces might be useful for deliberate electron beam guided movement of nanoparticles.

► We investigate the interaction of metal nanoparticles with a high energy electron beam.
► We find forces ranging from 0.1 to 50 pN forces between the metal particles and the beam.
► At moderate distances, dielectric forces are usually small and attractive.
► At sub-Nm distances the forces become repulsive, pushing nanoparticles away from the electron beam.
► While the repulsive behavior is predicted by electromagnetic theory, the detailed origin of the behavior is not yet understood.