Design and performance of a vacuum-UV simulator for material testing under space conditions

TL;DR

This paper presents the design, calibration, and performance evaluation of a vacuum-UV simulator capable of generating radiation below 115 nm for material testing under space-like conditions, enabling accelerated degradation studies.

Contribution

It introduces a novel VUV-simulator that produces radiation down to 40 nm, filling a gap in existing UV sources for space material testing, with detailed calibration and spectral analysis.

Findings

Achieved spectral irradiance from 24 to 58 mW/m² in the VUV range.

Generated spectral lines from gas constituents and metal atoms.

Reaches acceleration factors up to 26.3 Solar Constants.

Abstract

This paper describes the construction and performance of a VUV-simulator that has been designed to study degradation of materials under space conditions. It is part of the Complex Irradiation Facility at DLR in Bremen, Germany, that has been built for testing of material under irradiation in the complete UV-range as well as under proton and electron irradiation. Presently available UV-sources used for material tests do not allow the irradiation with wavelengths smaller than about $115$ nm where common Deuterium lamps show an intensity cut-off. The VUV-simulator generates radiation by excitation of a gas-flow with an electron beam. The intensity of the radiation can be varied by manipulating the gas-flow and/or the electron beam. The VUV simulator has been calibrated at three different gas-flow settings in the range from $40$ nm to $410$ nm. The calibration has been made by the Physikalisch-Technische Bundesanstalt (PTB) in Berlin. The measured spectra show total irradiance intensities from $24$ to $58$ mW$\rm{m^{-2}}$ (see Table 4.2) in the VUV-range, i.e. for wavelengths smaller than $200$ nm. They exhibit a large number of spectral lines generated either by the gas-flow constituents or by metal atoms in the residual gas which come from metals used in the source construction. In the range from $40$ nm to $120$ nm where Deuterium lamps are not usable, acceleration factors of $3$ to $26.3$ Solar Constants are reached depending on the gas-flow setting. The VUV-simulator allows studies of general degradation effects caused by photoionization and photodissociation as well as accelerated degradation tests by use of intensities that are significantly higher compared to that of the Sun at $1$ AU.