Controllable perfect spatiotemporal optical vortices

TL;DR

This paper introduces perfect spatiotemporal optical vortices (PSTOVs), a new class of structured light pulses with nearly charge-independent intensity profiles, controllable mode shapes, and confirmed experimental generation, broadening applications in photonics.

Contribution

The paper presents the concept of PSTOVs with charge-independent intensity profiles and demonstrates their generation and shape control via phase modulation, advancing structured light technology.

Findings

PSTOVs have nearly charge-independent intensity distributions.

Arbitrary mode shapes can be achieved through phase modulation.

Experimental generation of PSTOVs confirms theoretical predictions.

Abstract

Spatiotemporal optical vortices (STOVs), as a kind of structured light pulses carrying transverse orbital angular momentum (OAM), have recently attracted significant research interest due to their unique photonic properties. However, general STOV pulses typically exhibit an annular intensity profile in the spatiotemporal plane, with a radius that scales with the topological charge, limiting their potential in many applications. Here, to address this limitation, we introduce the concept of perfect spatiotemporal optical vortices (PSTOVs). Unlike STOV pulses, the intensity distribution of PSTOV wavepackets is nearly independent of the topological charge. We show that such wavepackets can be generated by applying the spatiotemporal Fourier transform to a Bessel-Gaussian mode in the spatiotemporal frequency domain. More importantly, the mode distribution of PSTOV wavepackets can be freely controlled by introducing azimuthal-dependent phase modulation, enabling conversion from a standard annular profile to arbitrary polygonal shapes. Finally, experimental results confirm the successful generation of these wavepackets. Our findings will expand the study of STOV pulses and explore their potential applications in optical communications, information processing, topological photonics, and ultrafast control of light-matter interactions.