Measurement of the Positive Muon Anomalous Magnetic Moment to 0.46 ppm

Abi, B.; Albahri, T.; Al-Kilani, S.; Allspach, D.; Alonzi, L.  P.; Anastasi, A.; Anisenkov, A.; Azfar, F.; Badgley, K.; Baeßler, S.; Bailey, I.; Baranov, V.  A.; Barlas-Yucel, E.; Barrett, T.; Barzi, E.; Basti, A.; Bedeschi, F.; Behnke, A.; Berz, M.; Bhattacharya, M.; Binney, H.  P.; Bjorkquist, R.; Bloom, P.; Bono, J.; Bottalico, E.; Bowcock, T.; Boyden, D.; Cantatore, G.; Carey, R.  M.; Carroll, J.; Casey, B.  C.  K.; Cauz, D.; Ceravolo, S.; Chakraborty, R.; Chang, S.  P.; Chapelain, A.; Chappa, S.; Charity, S.; Chislett, R.; Choi, J.; Chu, Z.; Chupp, T.  E.; Convery, M.  E.; Conway, A.; Corradi, G.; Corrodi, S.; Cotrozzi, L.; Crnkovic, J.  D.; Dabagov, S.; De Lurgio, P.  M.; Debevec, P.  T.; Di Falco, S.; Di Meo, P.; Di Sciascio, G.; Di Stefano, R.; Drendel, B.; Driutti, A.; Duginov, V.  N.; Eads, M.; Eggert, N.; Epps, A.; Esquivel, J.; Farooq, M.; Fatemi, R.; Ferrari, C.; Fertl, M.; Fiedler, A.; Fienberg, A.  T.; Fioretti, A.; Flay, D.; Foster, S.  B.; Friedsam, H.; Frlež, E.; Froemming, N.  S.; Fry, J.; Fu, C.; Gabbanini, C.; Galati, M.  D.; Ganguly, S.; Garcia, A.; Gastler, D.  E.; George, J.; Gibbons, L.  K.; Gioiosa, A.; Giovanetti, K.  L.; Girotti, P.; Gohn, W.; Gorringe, T.; Grange, J.; Grant, S.; Gray, F.; Haciomeroglu, S.; Hahn, D.; Halewood-Leagas, T.; Hampai, D.; Han, F.; Hazen, E.; Hempstead, J.; Henry, S.; Herrod, A.  T.; Hertzog, D.  W.; Hesketh, G.; Hibbert, A.; Hodge, Z.; Holzbauer, J.  L.; Hong, K.  W.; Hong, R.; Iacovacci, M.; Incagli, M.; Johnstone, C.; Johnstone, J.  A.; Kammel, P.; Kargiantoulakis, M.; Karuza, M.; Kaspar, J.; Kawall, D.; Kelton, L.; Keshavarzi, A.; Kessler, D.; Khaw, K.  S.; Khechadoorian, Z.; Khomutov, N.  V.; Kiburg, B.; Kiburg, M.; Kim, O.; Kim, S.  C.; Kim, Y.  I.; King, B.; Kinnaird, N.; Korostelev, M.; Kourbanis, I.; Kraegeloh, E.; Krylov, V.  A.; Kuchibhotla, A.; Kuchinskiy, N.  A.; Labe, K.  R.; Labounty, J.; Lancaster, M.; Lee, M.  J.; Lee, S.; Leo, S.; Li, B.; Li, D.; Li, L.; Logashenko, I.; Lorente Campos, A.; Lucà, A.; Lukicov, G.; Luo, G.; Lusiani, A.; Lyon, A.  L.; Maccoy, B.; Madrak, R.; Makino, K.; Marignetti, F.; Mastroianni, S.; Maxfield, S.; Mcevoy, M.; Merritt, W.; Mikhailichenko, A.  A.; Miller, J.  P.; Miozzi, S.; Morgan, J.  P.; Morse, W.  M.; Mott, J.; Motuk, E.; Nath, A.; Newton, D.; Nguyen, H.; Oberling, M.; Osofsky, R.; Ostiguy, J. -F.; Park, S.; Pauletta, G.; Piacentino, G.  M.; Pilato, R.  N.; Pitts, K.  T.; Plaster, B.; Počanić, D.; Pohlman, N.; Polly, C.  C.; Popovic, M.; Price, J.; Quinn, B.; Raha, N.; Ramachandran, S.; Ramberg, E.; Rider, N.  T.; Ritchie, J.  L.; Roberts, B.  L.; Rubin, D.  L.; Santi, L.; Sathyan, D.; Schellman, H.; Schlesier, C.; Schreckenberger, A.; Semertzidis, Y.  K.; Shatunov, Y.  M.; Shemyakin, D.; Shenk, M.; Sim, D.; Smith, M.  W.; Smith, A.; Soha, A.  K.; Sorbara, M.; Stöckinger, D.; Stapleton, J.; Still, D.; Stoughton, C.; Stratakis, D.; Strohman, C.; Stuttard, T.; Swanson, H.  E.; Sweetmore, G.; Sweigart, D.  A.; Syphers, M.  J.; Tarazona, D.  A.; Teubner, T.; Tewsley-Booth, A.  E.; Thomson, K.; Tishchenko, V.; Tran, N.  H.; Turner, W.; Valetov, E.; Vasilkova, D.; Venanzoni, G.; Volnykh, V.  P.; Walton, T.; Warren, M.; Weisskopf, A.; Welty-Rieger, L.; Whitley, M.; Winter, P.; Wolski, A.; Wormald, M.; Wu, W.; Yoshikawa, C.

doi:10.1103/PhysRevLett.126.141801

We present the first results of the Fermilab Muon g-2 Experiment for the positive muon magnetic anomaly aμ≡(gμ−2)/2. The anomaly is determined from the precision measurements of two angular frequencies. Intensity variation of high-energy positrons from muon decays directly encodes the difference frequency ωa between the spin-precession and cyclotron frequencies for polarized muons in a magnetic storage ring. The storage ring magnetic field is measured using nuclear magnetic resonance probes calibrated in terms of the equivalent proton spin precession frequency ω~′p in a spherical water sample at 34.7∘C. The ratio ωa/ω~′p, together with known fundamental constants, determines aμ(FNAL)=116592040(54)×10−11 (0.46,ppm). The result is 3.3 standard deviations greater than the standard model prediction and is in excellent agreement with the previous Brookhaven National Laboratory (BNL) E821 measurement. After combination with previous measurements of both μ+ and μ−, the new experimental average of aμ(Exp)=116592061(41)×10−11 (0.35,ppm) increases the tension between experiment and theory to 4.2 standard deviations

Measurement of the Positive Muon Anomalous Magnetic Moment to 0.46 ppm

Abi, B.;Albahri, T.;Al-Kilani, S.;Allspach, D.;Alonzi, L. P.;Anastasi, A.;Anisenkov, A.;Azfar, F.;Badgley, K.;Baeßler, S.;Bailey, I.;Baranov, V. A.;Barlas-Yucel, E.;Barrett, T.;Barzi, E.;Basti, A.;Bedeschi, F.;Behnke, A.;Berz, M.;Bhattacharya, M.;Binney, H. P.;Bjorkquist, R.;Bloom, P.;Bono, J.;Bottalico, E.;Bowcock, T.;Boyden, D.;Cantatore, G.;Carey, R. M.;Carroll, J.;Casey, B. C. K.;Cauz, D.;Ceravolo, S.;Chakraborty, R.;Chang, S. P.;Chapelain, A.;Chappa, S.;Charity, S.;Chislett, R.;Choi, J.;Chu, Z.;Chupp, T. E.;Convery, M. E.;Conway, A.;Corradi, G.;Corrodi, S.;Cotrozzi, L.;Crnkovic, J. D.;Dabagov, S.;De Lurgio, P. M.;Debevec, P. T.;Di Falco, S.;Di Meo, P.;Di Sciascio, G.;Di Stefano, R.;Drendel, B.;Driutti, A.;Duginov, V. N.;Eads, M.;Eggert, N.;Epps, A.;Esquivel, J.;Farooq, M.;Fatemi, R.;Ferrari, C.;Fertl, M.;Fiedler, A.;Fienberg, A. T.;Fioretti, A.;Flay, D.;Foster, S. B.;Friedsam, H.;Frlež, E.;Froemming, N. S.;Fry, J.;Fu, C.;Gabbanini, C.;Galati, M. D.;Ganguly, S.;Garcia, A.;Gastler, D. E.;George, J.;Gibbons, L. K.;Gioiosa, A.;Giovanetti, K. L.;Girotti, P.;Gohn, W.;Gorringe, T.;Grange, J.;Grant, S.;Gray, F.;Haciomeroglu, S.;Hahn, D.;Halewood-Leagas, T.;Hampai, D.;Han, F.;Hazen, E.;Hempstead, J.;Henry, S.;Herrod, A. T.;Hertzog, D. W.;Hesketh, G.;Hibbert, A.;Hodge, Z.;Holzbauer, J. L.;Hong, K. W.;Hong, R.;Iacovacci, M.;Incagli, M.;Johnstone, C.;Johnstone, J. A.;Kammel, P.;Kargiantoulakis, M.;Karuza, M.;Kaspar, J.;Kawall, D.;Kelton, L.;Keshavarzi, A.;Kessler, D.;Khaw, K. S.;Khechadoorian, Z.;Khomutov, N. V.;Kiburg, B.;Kiburg, M.;Kim, O.;Kim, S. C.;Kim, Y. I.;King, B.;Kinnaird, N.;Korostelev, M.;Kourbanis, I.;Kraegeloh, E.;Krylov, V. A.;Kuchibhotla, A.;Kuchinskiy, N. A.;Labe, K. R.;LaBounty, J.;Lancaster, M.;Lee, M. J.;Lee, S.;Leo, S.;Li, B.;Li, D.;Li, L.;Logashenko, I.;Lorente Campos, A.;Lucà, A.;Lukicov, G.;Luo, G.;Lusiani, A.^{Writing – Review & Editing};Lyon, A. L.;MacCoy, B.;Madrak, R.;Makino, K.;Marignetti, F.;Mastroianni, S.;Maxfield, S.;McEvoy, M.;Merritt, W.;Mikhailichenko, A. A.;Miller, J. P.;Miozzi, S.;Morgan, J. P.;Morse, W. M.;Mott, J.;Motuk, E.;Nath, A.;Newton, D.;Nguyen, H.;Oberling, M.;Osofsky, R.;Ostiguy, J. -F.;Park, S.;Pauletta, G.;Piacentino, G. M.;Pilato, R. N.;Pitts, K. T.;Plaster, B.;Počanić, D.;Pohlman, N.;Polly, C. C.;Popovic, M.;Price, J.;Quinn, B.;Raha, N.;Ramachandran, S.;Ramberg, E.;Rider, N. T.;Ritchie, J. L.;Roberts, B. L.;Rubin, D. L.;Santi, L.;Sathyan, D.;Schellman, H.;Schlesier, C.;Schreckenberger, A.;Semertzidis, Y. K.;Shatunov, Y. M.;Shemyakin, D.;Shenk, M.;Sim, D.;Smith, M. W.;Smith, A.;Soha, A. K.;Sorbara, M.;Stöckinger, D.;Stapleton, J.;Still, D.;Stoughton, C.;Stratakis, D.;Strohman, C.;Stuttard, T.;Swanson, H. E.;Sweetmore, G.;Sweigart, D. A.;Syphers, M. J.;Tarazona, D. A.;Teubner, T.;Tewsley-Booth, A. E.;Thomson, K.;Tishchenko, V.;Tran, N. H.;Turner, W.;Valetov, E.;Vasilkova, D.;Venanzoni, G.;Volnykh, V. P.;Walton, T.;Warren, M.;Weisskopf, A.;Welty-Rieger, L.;Whitley, M.;Winter, P.;Wolski, A.;Wormald, M.;Wu, W.;Yoshikawa, C.

2021

Abstract

We present the first results of the Fermilab Muon g-2 Experiment for the positive muon magnetic anomaly aμ≡(gμ−2)/2. The anomaly is determined from the precision measurements of two angular frequencies. Intensity variation of high-energy positrons from muon decays directly encodes the difference frequency ωa between the spin-precession and cyclotron frequencies for polarized muons in a magnetic storage ring. The storage ring magnetic field is measured using nuclear magnetic resonance probes calibrated in terms of the equivalent proton spin precession frequency ω~′p in a spherical water sample at 34.7∘C. The ratio ωa/ω~′p, together with known fundamental constants, determines aμ(FNAL)=116592040(54)×10−11 (0.46,ppm). The result is 3.3 standard deviations greater than the standard model prediction and is in excellent agreement with the previous Brookhaven National Laboratory (BNL) E821 measurement. After combination with previous measurements of both μ+ and μ−, the new experimental average of aμ(Exp)=116592061(41)×10−11 (0.35,ppm) increases the tension between experiment and theory to 4.2 standard deviations

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	Anno di pubblicazione
	
			2021
		
	Settore Scientifico Disciplinare
	
			Settore FIS/01 - Fisica Sperimentale
		
	Titolo Rivista
	
			PHYSICAL REVIEW LETTERS
		
	DOI
	
			https://dx.doi.org/10.1103/PhysRevLett.126.141801
		
	Parole chiave
	
			muon; anomalous magnetic moment
		
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11384/102327

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Measurement of the Positive Muon Anomalous Magnetic Moment to 0.46 ppm

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2021

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