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Autores principales: Alpat, Ali Behcet, Bartolini, Giovanni, Wusimanjiang, Talifujiang, Mattausch, Goesta, Teichmann, Tobias, Bluethner, Ralf, Müller, Michael Thomas, Zschech, Carsten, Coban, Abdullah, Bozkurt, Arca
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2402.06027
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author Alpat, Ali Behcet
Bartolini, Giovanni
Wusimanjiang, Talifujiang
Mattausch, Goesta
Teichmann, Tobias
Bluethner, Ralf
Müller, Michael Thomas
Zschech, Carsten
Coban, Abdullah
Bozkurt, Arca
author_facet Alpat, Ali Behcet
Bartolini, Giovanni
Wusimanjiang, Talifujiang
Mattausch, Goesta
Teichmann, Tobias
Bluethner, Ralf
Müller, Michael Thomas
Zschech, Carsten
Coban, Abdullah
Bozkurt, Arca
contents Materials to be deployed in space applications have to undergo a variety of different test scenarios, simulating actual space conditions. Among these materials solar photovoltaic cells, optics, meta-materials and more will be directly exposed to space radiation and must be tested accordingly. From the design phase of such target materials to the final production, it is important to obtain information about their behavior and performance in defined irradiation scenarios and qualify them following the directions of relevant ECSS/ESA standards. An excellent method to cover part of these tests in a laboratory scale is the high-flux, high-fluence electron irradiation with the help of industrial electron beam generators. The present collaboration has developed different irradiation test setups and procedures, adapted to the existing electron beam generators at IPF in Dresden, Germany covering an energy range between 100 keV to 1.5 MeV. The test setups, aiming for high electron flux, uniform and large irradiation field sizes, and their capabilities for use in irradiation qualification tests for space applications are described in this paper.
format Preprint
id arxiv_https___arxiv_org_abs_2402_06027
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Low Energy, High Flux, Uniform and Large Field Size Electron Beam Facility
Alpat, Ali Behcet
Bartolini, Giovanni
Wusimanjiang, Talifujiang
Mattausch, Goesta
Teichmann, Tobias
Bluethner, Ralf
Müller, Michael Thomas
Zschech, Carsten
Coban, Abdullah
Bozkurt, Arca
High Energy Physics - Experiment
Instrumentation and Detectors
Materials to be deployed in space applications have to undergo a variety of different test scenarios, simulating actual space conditions. Among these materials solar photovoltaic cells, optics, meta-materials and more will be directly exposed to space radiation and must be tested accordingly. From the design phase of such target materials to the final production, it is important to obtain information about their behavior and performance in defined irradiation scenarios and qualify them following the directions of relevant ECSS/ESA standards. An excellent method to cover part of these tests in a laboratory scale is the high-flux, high-fluence electron irradiation with the help of industrial electron beam generators. The present collaboration has developed different irradiation test setups and procedures, adapted to the existing electron beam generators at IPF in Dresden, Germany covering an energy range between 100 keV to 1.5 MeV. The test setups, aiming for high electron flux, uniform and large irradiation field sizes, and their capabilities for use in irradiation qualification tests for space applications are described in this paper.
title Low Energy, High Flux, Uniform and Large Field Size Electron Beam Facility
topic High Energy Physics - Experiment
Instrumentation and Detectors
url https://arxiv.org/abs/2402.06027