High-flux 100-kHz attosecond pulse source driven by a high average power annular laser beam

TL;DR

This paper reports a novel high-flux, 100-kHz attosecond pulse source driven by an annular laser beam, achieving record energy levels and high transmission efficiency for time-resolved electron dynamics studies.

Contribution

The study introduces an innovative annular beam shaping technique to generate high-energy, high-repetition-rate attosecond pulses with improved efficiency and demonstrates its advantages both experimentally and theoretically.

Findings

Achieved 51 pJ/shot attosecond pulse energy at 100 kHz.

Realized 19% transmission efficiency from generation to target.

Demonstrated the effectiveness of annular beam shaping for high-power attosecond pulse generation.

Abstract

High-repetition-rate attosecond pulse sources are indispensable tools of time-resolved studies of electron dynamics, such as coincidence spectroscopy and experiments with high demands on statistics or signal-to-noise ratio, especially in case of solid and big molecule samples in chemistry and biology. Although with the high-repetition-rate lasers such attosecond pulses in a pump-probe configuration are possible to achieve, until now only a few such light sources have been demonstrated. Here, by shaping the driving laser to an annular beam, a 100-kHz attosecond pulse train (APT) is reported with the highest energy so far (51 pJ/shot) on target (269 pJ at generation) among the high-repetition-rate systems (> 10 kHz) in which the attosecond pulses were temporally characterized. The on-target pulse energy is maximized by reducing the losses from the reflections and filtering of the high harmonics, and an unprecedented 19% transmission rate from the generation point to the target position is achieved. At the same time, the probe beam is also annular, and low loss of this beam is reached by using another holey mirror to combine with the APT. The advantages of using an annular beam to generate attosecond pulses with a high average power laser is demonstrated experimentally and theoretically. The effect of nonlinear propagation in the generation medium on the annular-beam generation concept is also analyzed in detail.