Line shape analysis of the K$\beta$ transition in muonic hydrogen

A. Gruber; A. Hirtl; D.F. Anagnostopoulos; D. Gotta; D.S. Covita; E.-O. Le Bigot; H. Fuhrmann; H. Gorke; J.F.C.A. Veloso; J.M.F. dos Santos

arxiv: 1709.05950 · v2 · pith:DT3TMV7Ynew · submitted 2017-09-18 · ⚛️ physics.atom-ph · nucl-ex

Line shape analysis of the Kβ transition in muonic hydrogen

D.S. Covita , D.F. Anagnostopoulos , H. Fuhrmann , H. Gorke , D. Gotta , A. Gruber , A. Hirtl , T. Ishiwatari

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P. Indelicato T.S. Jensen E.-O. Le Bigot V.E. Markushin M. Nekipelov V.N. Pomerantsev V.P. Popov J.M.F. dos Santos Ph. Schmid L.M. Simons M. Theisen M. Trassinelli J.F.C.A. Veloso J. Zmeskal

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classification ⚛️ physics.atom-ph nucl-ex

keywords betadistributionenergyhydrogenhyperfinekineticmuonicratio

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The K$\beta$ transition in muonic hydrogen was measured with a high-resolution crystal spectrometer. The spectrum is shown to be sensitive to the ground-state hyperfine splitting, the corresponding triplet-to-singlet ratio, and the kinetic energy distribution in the $3p$ state. The hyperfine splitting and triplet-to-singlet ratio are found to be consistent with the values expected from theoretical and experimental investigations and, therefore, were fixed accordingly in order to reduce the uncertainties in the further reconstruction of the kinetic energy distribution. The presence of high-energetic components was established and quantified in both a phenomenological, i.e. cascade-model-free fit, and in a direct deconvolution of the Doppler broadening based on the Bayesian approach.

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Line shape analysis of the Kβ transition in muonic hydrogen

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