Steps towards the hyperfine splitting measurement of the muonic hydrogen ground state: pulsed muon beam and detection system characterization

Adamczak, A.; Baccolo, Giovanni; Bakalov, D.; Baldazzi, G.; Bertoni, R.; Bonesini, M.; Bonvicini, V.; Campana, R.; Carbone, R. M.; Cervi, T.; Chignoli, F.; Clemenza, M.; Colace, Lorenzo; Curioni, A.; Danailov, M.B.; Danev, P.; D’Antone, I.; Bari, A. de; Vecchi, C. De; Vincenzi, M. De; Furini, M.; Fuschino, F.; Gadedjisso-Tossou, K. S.; Guffanti, D.; Iaciofano, A.; Ishida, K.; Iugovaz, D.; Labanti, C.; Maggi, Valter; Margotti, A.; Marisaldi, M.; Mazza, R.; Meneghini, S.; Menegolli, A.; Mocchiutti, E.; Moretti, Massimiliano; Morgante, G.; Nardo, R. Di; Nastasi, M.; Niemela, Joseph; Previtali, E.; Ramponi, Roberta; Rachevski, A.; Rignanese, L. P.; Rossella, M.; Rossi, Pier Luca; Somma, Fabrizia; Stoilov, Michail; Stoychev, L.; Tomaselli, Alessandra; Tortora, L.; Vacchi, A.; Vallazza, E.; Zampa, G.; Zuffa, M.

doi:10.1088/1748-0221/11/05/p05007

Cited by 43 publications

(44 citation statements)

References 20 publications

(24 reference statements)

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“…1, is a limiting factor extracting radii from the muonic hydrogen spectroscopy [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Moreover, an accurate evaluation of two-photon corrections to hyperfine splitting (HFS) of ground state in electronic hydrogen in combination with an excellent experimental knowledge [26][27][28][29][30][31][32][33][34][35][36][37][38][39][40] (known with mHz accuracy) could help to analyse future precise measurements of 1S HFS in muonic hydrogen [41][42][43][44], which aim to decrease an uncertainty of 1S-level HFS from the level of 40 µeV [2] up to the level of 0.2 µeV. Though the two-photon correction is smaller than the modern accuracy of Lamb shift measurements in usual hydrogen, it can affect the precisely measurable 1S-2S transition [45,46] (with the experimental uncertainty 10-11 Hz), as well as the isotope shift [47,48] (with the experimental uncertainty 15 Hz), above the accuracy level of the difference between proton and deuteron charge radii [25,…”

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confidence: 99%

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Two-photon exchange correction to the Lamb shift and hyperfine splitting of S levels

Tomalak

2019

Eur. Phys. J. A

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We evaluate the two-photon exchange corrections to the Lamb shift and hyperfine splitting of S states in electronic hydrogen relying on modern experimental data and present the two-photon exchange on a neutron inside the electronic and muonic atoms. These results are relevant for the precise extraction of the isotope shift as well as in the analysis of the ground state hyperfine splitting in usual and muonic hydrogen.The discrepancy between the proton charge radius extractions from the Lamb shift in muonic hydrogen [1,2] and electron-proton scattering [3-5] triggered a lot of theoretical and experimental efforts both in scattering and spectroscopy, see Refs. [6,7] for recent reviews. Twophoton exchange (TPE) hadronic correction, see Fig. 1, is a limiting factor extracting radii from the muonic hydrogen spectroscopy [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Moreover, an accurate evaluation of two-photon corrections to hyperfine splitting (HFS) of ground state in electronic hydrogen in combination with an excellent experimental knowledge [26][27][28][29][30][31][32][33][34][35][36][37][38][39][40] (known with mHz accuracy) could help to analyse future precise measurements of 1S HFS in muonic hydrogen [41][42][43][44], which aim to decrease an uncertainty of 1S-level HFS from the level of 40 µeV [2] up to the level of 0.2 µeV. Though the two-photon correction is smaller than the modern accuracy of Lamb shift measurements in usual hydrogen, it can affect the precisely measurable 1S-2S transition [45,46] (with the experimental uncertainty 10-11 Hz), as well as the isotope shift [47,48] (with the experimental uncertainty 15 Hz), above the accuracy level of the difference between proton and deuteron charge radii [25,49]. In the latter references, the elastic Friar term [50] was accounted for and the inelastic correction was estimated in the leading logarithmic approximation [51][52][53]. Besides two-photon corrections, the more involved three-photon exchange contribution to the Lamb shift was recently evaluated in the nonrecoil limit neglecting magnetic dipole and electric quadrupole moments of the nucleus in Ref. [49]. FIG. 1: Two-photon exchange graph.In this paper, we provide a first complete dispersive calculation of α 5 two-photon exchange contribution to the Lamb shift in electronic hydrogen, summarize the current status of this correction to the hyperfine splitting of S states and provide an update of Ref.[40] for S-level HFS in µH. Additionally, we present contributions to the Lamb shift arising from the two-photon exchange on the neutron inside a nucleus.We evaluate the correction to the Lamb shift of S energy levels E LS following Refs. [8,13]. It can be expressed as a sum of three terms:the Born contribution E Born , the subtraction term E subt and the inelastic correction E inel . To evaluate the dimensionless forward unpolarized amplitude, we always normalize the TPE contributions to the energy E 0 :where M is the proton mass, m is the lepton mass, |ψ nS (0)| 2 = α 3 m 3 r /(πn...

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confidence: 99%

“…We presented the current knowledge of the TPE correction to S energy levels. The Lamb shift results can be useful in future extractions of the isotope shift, while the contributions to the hyperfine splitting can help to tune and analyze forthcoming 1S HFS measurements in µH [41][42][43][44].…”

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confidence: 99%

Two-photon exchange correction to the Lamb shift and hyperfine splitting of S levels

Tomalak

2019

Eur. Phys. J. A

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“…In the practical use of (31) - (32) , it is convenient to single out the contributions of the symmetric and antisymmetric parts of the projection operators. The general structure of the amplitudes and interaction potentials of particles in these states has the same form as (13), (17), (21), (22), and the intervals of the hyperfine structure themselves are determined by formulas similar to (23):…”

Section: General Formalismmentioning

confidence: 99%

“…Only in the case of simple two particle bound states the theoretical methods are well developed to calculate the energy levels including nuclear effects from first principles. In general, it can be noted that the program for studying muon systems is gaining momentum: a precision study of the ground state hyperfine structure of muonic hydrogen, the energy interval (1S − 2S), and the processes of production of dimuonium are planned [10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Hyperfine structure of P states in muonic ions of lithium, beryllium, and boron

Dorokhov¹,

Martynenko²,

Martynenko³

et al. 2019

Phys. Rev. A

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We calculate hyperfine structure intervals ∆E hf s (2P 1/2 ) and ∆E hf s (2P 3/2 ) for P-states in muonic ions of lithium, beryllium and boron. To construct the particle interaction operator in momentum space we use the tensor method of projection operators on states with definite quantum numbers of total atomic momentum F and total muon momentum j. We take into account vacuum polarization, relativistic, quadruple and structure corrections of orders α 4 , α 5 and α 6 . The obtained numerical values of hyperfine splittings can be used for a comparison with future experimental data of the CREMA collaboration.

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“…4,TPE from hyperfine splitting in muonic hydrogen The possibility of measuring the hyperfine splitting in muonic hydrogen has be come a reality in recent years: [31][32][33][34]. Actually an experimental number has been given for the 2S hyperfine splitting in ref.…”

Section: Determination Of C Pµmentioning

confidence: 99%

Model-independent determination of the two-photon exchange contribution to hyperfine splitting in muonic hydrogen

Peset

Pineda

2017

J. High Energ. Phys.

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We obtain a model-independent prediction for the two-photon exchange contribution to the hyperfine splitting in muonic hydrogen. We use the relation of the Wilson coefficients of the spin-dependent dimension-six four-fermion operator of NRQED applied to the electron-proton and to the muon-proton sectors. Their difference can be reliably computed using chiral perturbation theory, whereas the Wilson coefficient of the electronproton sector can be determined from the hyperfine splitting in hydrogen. This allows us to give a precise model-independent determination of the Wilson coefficient for the muonproton sector, and consequently of the two-photon exchange contribution to the hyperfine splitting in muonic hydrogen, which reads δĒ TPE pµ,HF (nS) = − 1 n 3 1.161(20) meV. Together with the associated QED analysis, we obtain a prediction for the hyperfine splitting in muonic hydrogen that reads E th pµ,HF (1S) = 182.623(27) meV and E th pµ,HF (2S) = 22.8123(33) meV. The error is dominated by the two-photon exchange contribution.

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Steps towards the hyperfine splitting measurement of the muonic hydrogen ground state: pulsed muon beam and detection system characterization

Cited by 43 publications

References 20 publications

Two-photon exchange correction to the Lamb shift and hyperfine splitting of S levels

Two-photon exchange correction to the Lamb shift and hyperfine splitting of S levels

Hyperfine structure of P states in muonic ions of lithium, beryllium, and boron

Model-independent determination of the two-photon exchange contribution to hyperfine splitting in muonic hydrogen

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