Radio-pure materials and technologies for science and society (Q84231): Difference between revisions
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Matériaux et technologies radio-pures pour la science et la société |
Revision as of 16:24, 30 November 2021
Project Q84231 in Poland
Language | Label | Description | Also known as |
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English | Radio-pure materials and technologies for science and society |
Project Q84231 in Poland |
Statements
4,013,804.0 zloty
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4,013,804.0 zloty
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100.0 percent
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1 February 2017
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31 January 2021
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UNIWERSYTET JAGIELLOŃSKI
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For physics frontier experiments, designed to investigate fundamental problems of the Standard Model like non-conservation of lepton number (through neutrino-less double beta decay) or existence of dark matter particles, the expected signals are very week (~1 ev/year). The detectors need to have large active masses and simultaneously the background rates, caused by natural radioactivity, must be pushed down to extremely low levels. Comprehensive research program on the background reduction techniques is therefore proposed. It is based on world-wide unique expertise of the PI and, if completed, it will allow for better understanding of the origin of the most relevant isotopes, and for easier, faster and more confident selection of materials and procedures for applications with the highest radio-purity demands (single-atom level). Finally, the presented project will have crucial impact on future large-scale (ton-scale) experiments in the field of nuclear and astro-particle physics. (Polish)
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For physics frontier experiments, designed to investigate fundamental problems of the Standard Model like non-conservation of lepton number (through neutrino-less double beta decay) or existence of dark matter particles, the expected signals are very week (~1 ev/year). The detectors need to have large active masses and simultaneously the background rates, caused by natural Radioactivity, must be pushed down to extremely low levels. Comprehensive research program on the background reduction techniques is therefore proposed. It is based on world-wide unique expertise of the PI and, if completed, it will allow for better understanding of the origin of the most relevant isotopes, and for easier, faster and more confident selection of materials and procedures for applications with the highest radio-purity demands (single-atom level). Finally, the presented project will have a crucial impact on the future large-scale (ton-scale) experiments in the field of nuclear and astro-particle physics. (English)
14 October 2020
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Identifiers
POIR.04.04.00-00-2FFF/16
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