GRANIT project: a trap for gravitational quantum states of UCN

Previous studies of gravitationally bound states of ultracold neutrons showed the quantization of energy levels, and confirmed quantum mechanical predictions for the average size of the two lowest energy states wave functions. Improvements in position-like measurements can increase the accuracy by a...

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Bibliographic Details
Published in:arXiv.org 2007-08
Main Authors: Pignol, G, Protasov, K V, Rebreyend, D, Vezzu, F, Nesvizhevsky, V V, Petukhov, A K, Börner, H G, Soldner, T, Schmidt-Wellenburg, P, Kreuz, M, est, D, Ganau, P, Mackowski, J M, Michel, C, Montorio, J L, Morgado, N, Pinard, L, Remillieux, A, Gagarski, A M, Petrov, G A, Kusmina, A M, Strelkov, A V, Abele, H, Baeßler, S, A Yu Voronin
Format: Article
Language:English
Subjects:
Energy levels
Energy measurement
Neutrons
Perturbation
Position measurement
Quantum mechanics
Quantum theory
Wave functions
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Summary:Previous studies of gravitationally bound states of ultracold neutrons showed the quantization of energy levels, and confirmed quantum mechanical predictions for the average size of the two lowest energy states wave functions. Improvements in position-like measurements can increase the accuracy by an order of magnitude only. We therefore develop another approach, consisting in accurate measurements of the energy levels. The GRANIT experiment is devoted to the study of resonant transitions between quantum states induced by an oscillating perturbation. According to Heisenberg's uncertainty relations, the accuracy of measurement of the energy levels is limited by the time available to perform the transitions. Thus, trapping quantum states will be necessary, and each source of losses has to be controlled in order to maximize the lifetime of the states. We discuss the general principles of transitions between quantum states, and consider the main systematical losses of neutrons in a trap.
ISSN:2331-8422