Direct Experimental Observation of the Gas Filamentation Effect using a Two-bunch X-ray FEL Beam

TL;DR

This study experimentally demonstrates the gas filamentation effect in X-ray free-electron laser gas devices, showing how the first pulse reduces gas density and affects subsequent pulse attenuation, informing future high-repetition-rate FEL designs.

Contribution

First direct experimental observation of gas filamentation effect in X-ray FELs using a two-bunch beam at LCLS, revealing impact on pulse attenuation and device design.

Findings

Second pulse experiences less attenuation after passing through heated gas.

Gas density reduction caused by the first pulse affects subsequent pulse transmission.

Results inform design considerations for high-repetition-rate FEL gas devices.

Abstract

We report the experimental observation of the filamentation effect in gas devices designed for X-ray Free-electron Lasers. The measurements were carried out at the Linac Coherent Light Source on the X-ray Correlation Spectroscopy (XCS) instrument using a Two-bunch FEL beam at 6.5 keV with 122.5 ns separation passing through an Argon gas cell. The relative intensities of the two pulses of the Two-bunch beam were measured, after and before the gas cell, from the X-ray scattering off thin targets by using fast diodes with sufficient temporal resolution. It was found that the after-to-before ratio of the intensities of the second pulse was consistently higher than that of the first pulse, revealing lower effective attenuation of the gas cell due to the heating and subsequent gas density reduction in the beam path by the first pulse. This measurement is important in guiding the design and/or mitigating the adverse effect in gas devices for high repetition-rate FELs such as the LCLS-II and the European XFEL or other future high repetition-rate upgrade to existing FEL facilities