Isolated attosecond free-electron laser based on a sub-cycle driver from hollow capillary fibers

TL;DR

This paper proposes a novel method to generate high-intensity, isolated attosecond soft X-ray FELs using sub-cycle MIR pulses from hollow capillary fibers, enabling advanced electron dynamics studies.

Contribution

The paper introduces a new scheme utilizing sub-cycle MIR pulses from gas-filled hollow capillary fibers to produce isolated attosecond FEL pulses with high power and SNR.

Findings

Generated 1 nm wavelength pulse with ~28 GW peak power

Achieved pulse duration of approximately 600 attoseconds

Attained signal-to-noise ratio of about 96.4%

Abstract

The attosecond light source provides an advanced tool for investigating electron motion using time-resolved-spectroscopy techniques. Isolated attosecond pulses, especially, will significantly advance the study of electron dynamics. However, achieving high-intensity isolated attosecond pulses is still challenging at the present stage. In this paper, we propose a novel scheme for generating high-intensity, isolated attosecond soft X-ray free-electron lasers (FELs) using a mid-infrared (MIR) sub-cycle modulation laser from gas-filled hollow capillary fibers (HCFs). The multi-cycle MIR pulses are first compressed to sub-cycle using a helium-filled HCF with decreasing pressure gradient due to soliton self-compression effect. By utilizing such sub-cycle MIR laser pulse to modulate the electron beam, we can obtain a quasi-isolated current peak, which can then produce an isolated FEL pulse with high signal-to-noise ratio (SNR), naturally synchronizing with the sub-cycle MIR laser pulse. Numerical simulations have been carried out, including the sub-cycle pulse generation, electron beam modulation and FEL radiation processes. The simulation results indicate that an isolated attosecond pulse with wavelength of 1 nm, peak power of ~28 GW, pulse duration of ~600 attoseconds and SNR of ~96.4% can be generated by our proposed method. The numerical results demonstrated here pave a new way for generating the high-intensity isolated attosecond soft X-ray pulse, which may have many applications in nonlinear spectroscopy and atomic-site electronic process.