Abstract
Beams of light with a large topological charge significantly change their spatial structure when they are focused strongly. Physically, it can be explained by an emerging electromagnetic field component in the direction of propagation, which is neglected in the simplified scalar wave picture in optics. Here we ask: is this a specific photonic behavior, or can similar phenomena also be predicted for other species of particles? We show that the same modification of the spatial structure exists for relativistic electrons as well as for focused gravitational waves. However, this is for different physical reasons: for electrons, which are described by the Dirac equation, the spatial structure changes due to a spin–orbit coupling in the relativistic regime. In gravitational waves described with linearized general relativity, the curvature of space–time between the transverse and propagation direction leads to the modification of the spatial structure. Thus, this universal phenomenon exists for both massive and massless elementary particles with spin 1/2, 1 and 2. It would be very interesting whether other types of particles such as composite systems (neutrons or C60) or neutrinos show a similar behavior and how this phenomenon can be explained in a unified physical way.
Highlights
We found in theoretical calculations that the intensity structure of light with large topological charge changes greatly when it is focused [1]
Gravitational waves in free space can be described by linearized gravity, which is a weak-field solution of Einstein’s general relativity (GR) in the absence of matter
The paraxial, small-angle solutions for beams carrying orbital angular momentum predicts a curious, unphysical effect which would allow for breaking the Rayleigh criterion
Summary
Beams of light with a large topological charge significantly change their spatial structure when they are author(s) and the title of the work, journal citation focused strongly. It can be explained by an emerging electromagnetic field component in the and DOI. In gravitational waves described with linearized general relativity, the curvature of space–time between the transverse and propagation direction leads to the modification of the spatial structure. This universal phenomenon exists for both massive and massless elementary particles with spin 1/2, 1 and 2. It would be very interesting whether other types of particles such as composite systems (neutrons or C60) or neutrinos show a similar behavior and how this phenomenon can be explained in a unified physical way
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