On-target delivery of intense ultrafast laser pulses through hollow-core anti-resonant fibers

Abstract

We report the flexible on-target delivery of 800 nm wavelength, 5 GW peak power, 40 fs duration laser pulses through an evacuated and tightly coiled 10 m long hollow-core nested anti-resonant fiber by positively chirping the input pulses to compensate for the anomalous dispersion of the fiber. Near-transform-limited output pulses with high beam quality and a guided peak intensity of 3 PW/cm2 were achieved by suppressing plasma effects in the residual gas by pre-pumping the fiber with laser pulses after evacuation. This appears to cause a long-term removal of molecules from the fiber core. Identifying the fluence at the fiber core-wall interface as the damage origin, we scaled the coupled energy to 2.1 mJ using a short piece of larger-core fiber to obtain 20 GW at the fiber output. This scheme can pave the way towards the integration of anti-resonant fibers in mJ-level nonlinear optical experiments and laser-source development.

Publication
Opt. Express 31 30227 (2023)
Federico Belli
Federico Belli
Research Fellow
Christian Brahms
Christian Brahms
Assistant Professor
Mohammed Sabbah
Mohammed Sabbah
Research Associate
John C. Travers
John C. Travers
Professor of Physics