Tracing the phase of focused broadband laser pulses

TL;DR

This paper presents a direct 3D measurement of the optical phase of broadband laser pulses, revealing significant deviations from the traditional Gouy phase, which impacts various applications involving focused ultrashort laser pulses.

Contribution

It introduces a novel measurement method for the 3D phase of broadband laser pulses, demonstrating complex phase behavior beyond the classical Gouy phase model.

Findings

Measured phase deviates from Gouy phase in broadband pulses

Phase exhibits complex spatial dependence along propagation and radial directions

Implications for high-harmonic generation, attosecond science, and biomedical optics

Abstract

Precise knowledge of the behaviour of the phase of light in a focused beam is fundamental to understanding and controlling laser-driven processes. More than a hundred years ago an axial phase anomaly for focused monochromatic light beams was discovered and is now commonly known as the Gouy phase. Recent theoretical work has brought into question the validity of applying this monochromatic phase formulation to the broadband pulses becoming ubiquitous today. Based on electron back-scattering at sharp nanometre-scale metal tips, a method is available to measure light fields with sub-wavelength spatial resolution and sub-optical cycle time resolution. Here we report such a direct, three-dimensional measurement of the spatial dependence of the optical phase of a focused, 4-fs, near-infrared laser pulse. The observed optical phase deviates substantially from the monochromatic Gouy phase - exhibiting a much more complex spatial dependence, both along the propagation axis and in the radial direction. In our measurements, these significant deviations are the rule and not the exception for focused, broadband laser pulses. Therefore, we expect wide ramifications for all broadband laser-matter interactions, such as in high-harmonic and attosecond pulse generation, femtochemistry, ophthalmological optical coherence tomography and light-wave electronics.