Self-referencing 3D characterization of ultrafast optical-vortex beams using tilted interference TERMITES technique

TL;DR

This paper introduces a self-referencing tilted interferometer technique for complete 3D characterization of ultrafast optical vortex beams carrying orbital angular momentum, overcoming limitations of traditional methods.

Contribution

The authors develop a novel self-referencing method that measures the full spatio-temporal profile of ultrafast vortex beams without requiring a well-characterized reference beam.

Findings

Successfully reconstructed 3D spatio-temporal profiles of vortex beams.

Demonstrated measurement of spectral phase across the beam profile.

Enabled simultaneous retrieval of temporal envelope at phase singularities.

Abstract

Femtosecond light pulses carrying optical angular momentums (OAMs), possessing intriguing properties of helical phase fronts and ultrafast temporal profiles, enable many applications in nonlinear optics, strong-field physics and laser micro-machining. While generation of OAM-carrying ultrafast pulses and their interactions with matters have been intensively studied in experiments, three-dimensional characterization of ultrafast OAM-carrying light beams in spatio-temporal domain has, however, proved difficult to achieve. Conventional measurement schemes rely on the use of a reference pulsed light beam which needs to be well-characterized in its phase front and to have sufficient overlap and coherence with the beam under test, largely limiting practical applications of these schemes. Here we demonstrate a self-referencing set-up based on a tilted interferometer that can be used to measure complete spatio-temporal information of OAM-carrying femtosecond pulses with different topological charges. Through scanning one interferometer arm, the spectral phase over the pulse spatial profile can be obtained using the tilted interference signal, and the temporal envelope of the light field at one particular position around its phase singularity can be retrieved simultaneously, enabling three-dimensional beam reconstruction. This self-referencing technique, capable of measuring spatio-temporal ultrafast optical-vortex beams, may find many applications in fields of nonlinear optics and light-matter interactions.