Gas-filled cell as a narrow bandwidth bandpass filter in the VUV wavelength range

TL;DR

This paper introduces a novel narrow-bandwidth VUV filter using a resonantly absorbing gas cell, enabling single-mode laser beams for FEL applications with high efficiency and simplicity.

Contribution

It proposes a gas-based monochromator exploiting Fano resonances for effective spectral filtering in the VUV range, a novel approach for FEL beam control.

Findings

Achieves near-zero absorption at specific wavelengths due to Fano profiles.

Demonstrates feasibility for implementation in existing FEL facilities.

Provides a simple, efficient method for narrow-band VUV filtering.

Abstract

We propose a method for spectrally filtering radiation in the VUV wavelength range by means of a monochromator constituted by a cell filled with a resonantly absorbing rare gas. Around particular wavelengths, the gas exhibits narrow-bandwidth absorbing resonances following the Fano profile. In particular, within the photon energy range 60 eV - 65 eV, the correlation index of the Fano profiles for the photo-ionization spectra in Helium is equal to unity, meaning that the minimum of the cross-section is exactly zero. For sufficiently large column density in the gas cell, the spectrum of the incoming radiation will be attenuated by the background cross-section of many orders of magnitude, except for those wavelengths close to the point where the cross-section is zero. Remarkable advantages of a gas monochromator based on this principle are simplicity, efficiency and narrow-bandwidth. A gas monochromator installed in the experimental hall of a VUV SASE FEL facility would enable the delivery of a single-mode VUV laser beam. The design is identical to that of already existing gas attenuator systems for VUV or X-ray FELs. We present feasibility study and exemplifications for the FLASH facility in the VUV regime.