Robust isolated attosecond pulse generation with self-compressed sub-cycle drivers from hollow capillary fibers

TL;DR

This paper proposes a novel, CEP-robust method for generating isolated attosecond pulses using self-compressed multi-cycle drivers in hollow capillary fibers, enabling more practical and stable ultrafast light sources.

Contribution

It introduces a new scheme for IAP generation from multi-cycle drivers via soliton self-compression in HCFs, bypassing the need for near-single-cycle pulses.

Findings

High-contrast IAPs are emitted independently of CEP.

The scheme is stable under macroscopic propagation.

It enables integrated all-fiber IAP sources.

Abstract

High-order harmonic generation (HHG) arising from the non-perturbative interaction of intense light fields with matter constitutes a well-established tabletop source of coherent extreme-ultraviolet and soft X-ray radiation, which is typically emitted as attosecond pulse trains. However, ultrafast applications increasingly demand isolated attosecond pulses (IAPs), which offer great promise for advancing precision control of electron dynamics. Yet, the direct generation of IAPs typically requires the synthesis of near-single-cycle intense driving fields, which is technologically challenging. In this work, we theoretically demonstrate a novel scheme for the straightforward and compact generation of IAPs from multi-cycle infrared drivers using hollow capillary fibers (HCFs). Starting from a standard, intense multi-cycle infrared pulse, a light transient is generated by extreme soliton self-compression in a HCF with decreasing pressure, and is subsequently used to drive HHG in a gas target. Owing to the sub-cycle confinement of the HHG process, high-contrast IAPs are continuously emitted almost independently of the carrier-envelope phase (CEP) of the optimally self-compressed drivers. This results in a CEP-robust scheme which is also stable under macroscopic propagation of the high harmonics in a gas target. Our results open the way to a new generation of integrated all-fiber IAP sources, overcoming the efficiency limitations of usual gating techniques for multi-cycle drivers.