Cold antimatter for quantum state-resolved precision measurements
https://www.sciencedaily.com/releases/2024/08/240802132938.htm
Why does the universe contain matter and (virtually) no antimatter? Scientists have achieved an experimental breakthrough in this context. It can contribute to measuring the mass and magnetic moment of antiprotons more precisely than ever before -- and thus identify possible matter-antimatter asymmetries. They have developed a trap, which can cool individual antiprotons much more rapidly than in the past.
PepikHipik /
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2024-08-03 03:46:19
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2024-08-03 03:46:19Event JSON
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"content": "Cold antimatter for quantum state-resolved precision measurements\nhttps://www.sciencedaily.com/releases/2024/08/240802132938.htm\nWhy does the universe contain matter and (virtually) no antimatter? Scientists have achieved an experimental breakthrough in this context. It can contribute to measuring the mass and magnetic moment of antiprotons more precisely than ever before -- and thus identify possible matter-antimatter asymmetries. They have developed a trap, which can cool individual antiprotons much more rapidly than in the past.",
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