Twisted spatiotemporal optical vortex beams in dispersive media.

We derive a closed-form expression for the mutual coherence function (MCF) of a twisted spatiotemporal optical vortex (STOV) beam after propagating a distance z in a linear dispersive medium. A twisted STOV beam is a partially coherent optical field that possesses a coherent STOV and a stochastic twist coupling its space and time dimensions. These beams belong to a special class of space–time-coupled light fields that carry transverse (to the direction of propagation) orbital angular momentum, making them potentially useful in numerous applications including quantum optics, optical manipulation, and optical communications. After presenting the derivation, we validate our new general MCF by showing that it simplifies to the MCFs for two example beams from the literature. Lastly, we present and analyze space–time beam profiles and complex arguments (phases) of the MCF at multiple z and differing amounts of material dispersion, field correlation or coherence, and beam twist to gain insight into how twisted STOV beams evolve in dispersive media. We conclude with a brief summary. • We derive the MCF for a twisted STOV beam propagating in dispersive media. • A twisted STOV beam is a space–time-coupled (STC) field that carries transverse OAM. • We observe interesting propagation behaviors not predicted in prior works. • Our analysis will be useful in applying these STC beams in optical tweezing, optical communications, etc. [Display omitted] [ABSTRACT FROM AUTHOR]