Klaus-Peter Jungmann
University of Groningen
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Physical Review D | 2006
Gw Bennett; B. Bousquet; H. N. Brown; G. Bunce; R. M. Carey; P. Cushman; G. T. Danby; P. T. Debevec; M. Deile; H. Deng; S. Dhawan; V. P. Druzhinin; L. Duong; E. Efstathiadis; F. J. M. Farley; G. V. Fedotovich; S. Giron; F. Gray; D. Grigoriev; M. Grosse-Perdekamp; A. Grossmann; M. F. Hare; David W. Hertzog; X. Huang; V. W. Hughes; M. Iwasaki; Klaus-Peter Jungmann; D. Kawall; M. Kawamura; B. I. Khazin
We present the final report from a series of precision measurements of the muon anomalous magnetic moment, a(mu)=(g-2)/2. The details of the experimental method, apparatus, data taking, and analysis are summarized. Data obtained at Brookhaven National Laboratory, using nearly equal samples of positive and negative muons, were used to deduce a(mu)(Expt)=11659208.0(5.4)(3.3)x10(-10), where the statistical and systematic uncertainties are given, respectively. The combined uncertainty of 0.54 ppm represents a 14-fold improvement compared to previous measurements at CERN. The standard model value for a(mu) includes contributions from virtual QED, weak, and hadronic processes. While the QED processes account for most of the anomaly, the largest theoretical uncertainty, approximate to 0.55 ppm, is associated with first-order hadronic vacuum polarization. Present standard model evaluations, based on e(+)e(-) hadronic cross sections, lie 2.2-2.7 standard deviations below the experimental result.
Reports on Progress in Physics | 2009
A. Bandyopadhyay; S. Choubey; Raj Gandhi; Srubabati Goswami; B.L. Roberts; J. Bouchez; I. Antoniadis; John Ellis; Gian Francesco Giudice; Thomas Schwetz; S. Umasankar; G. Karagiorgi; A. A. Aguilar-Arevalo; J. M. Conrad; M. H. Shaevitz; Silvia Pascoli; S. Geer; J.E. Campagne; Mark Rolinec; A. Blondel; M. Campanelli; Joachim Kopp; Manfred Lindner; Juha T. Peltoniemi; P.J. Dornan; K. R. Long; T. Matsushita; C. Rogers; Y. Uchida; M. Dracos
The conclusions of the Physics Working Group of the International Scoping Study of a future Neutrino Factory and super-beam facility (the ISS) are presented. The ISS was carried out by the international community between NuFact05, (the 7th International Workshop on Neutrino Factories and Super-beams, Laboratori Nazionali di Frascati, Rome, 21–26 June 2005) and NuFact06 (Ivine, CA, 24–30 August 2006). The physics case for an extensive experimental programme to understand the properties of the neutrino is presented and the role of high-precision measurements of neutrino oscillations within this programme is discussed in detail. The performance of second-generation super-beam experiments, beta-beam facilities and the Neutrino Factory are evaluated and a quantitative comparison of the discovery potential of the three classes of facility is presented. High-precision studies of the properties of the muon are complementary to the study of neutrino oscillations. The Neutrino Factory has the potential to provide extremely intense muon beams and the physics potential of such beams is discussed in the final section of the report.The conclusions of the Physics Working Group of the International Scoping Study of a future Neutrino Factory and super-beam facility (the ISS) are presented. The ISS was carried out by the international community between NuFact05, (the 7th International Workshop on Neutrino Factories and Superbeams, Laboratori Nazionali di Frascati, Rome, June 21-26, 2005) and NuFact06 (Irvine, California, 2430 August 2006). The physics case for an extensive experimental programme to understand the properties of the neutrino is presented and the role of high-precision measurements of neutrino oscillations within this programme is discussed in detail. The performance of second generation super-beam experiments, beta-beam facilities, and the Neutrino Factory are evaluated and a quantitative comparison of the discovery potential of the three classes of facility is presented. High-precision studies of the properties of the muon are complementary to the study of neutrino oscillations. The Neutrino Factory has the potential to provide extremely intense muon beams and the physics potential of such beams is discussed in the final section of the report. The ISS Physics Working Group Editors: S.F. King1, K. Long2, Y. Nagashima3, B.L. Roberts4, and O. Yasuda5.
Physical Review Letters | 2004
F. J. M. Farley; Klaus-Peter Jungmann; J. P. Miller; W. M. Morse; Y. Orlov; Bradley Lee Roberts; Yannis K. Semertzidis; Alexander J. Silenko; E. J. Stephenson
A new highly sensitive method of looking for electric dipole moments of charged particles in storage rings is described. The major systematic errors inherent in the method are addressed and ways to minimize them are suggested. It seems possible to measure the muon EDM to levels that test speculative theories beyond the standard model.
Physical Review Letters | 1999
Lorenz Willmann; P. V. Schmidt; H. P. Wirtz; R. Abela; Vm Baranov; J Bagaturia; W. Bertl; R. Engfer; A. Grossmann; V. W. Hughes; Klaus-Peter Jungmann; Karpuchin; Kisel; A. Korenchenko; S. Korenchenko; N. Kravchuk; N. Kuchinsky; A Leuschner; B Meyer; J. Merkel; A. Moiseenko; D. Mzavia; G. zu Putlitz; W Reichart; S. Reinhard; D. Renker; T Sakhelashvilli; K Trager; H. K. Walter
A new upper limit for the probability of spontaneous muonium to antimuonium conversion was established at P-M (M over bar) less than or equal to 8.3 x 10(-11) (90% C.L.) in 0.1 T magnetic field, which implies consequences for speculative extensions to the standard model. Coupling parameters in R-parity-violating supersymmetry and the mass of a flavor diagonal bileptonic gauge boson can be significantly restricted. A Z(8) model with radiative mass generation through heavy lepton seed and the minimal version of 331 models are disfavored. [S0031-9007(98)08068-5].
Physical Review Letters | 2000
B Meyer; Sn Bagayev; P E G Baird; P Bakule; M.G. Boshier; A Breitruck; Simon L. Cornish; S Dychkov; G. H. Eaton; A Grossmann; D Hubl; V. W. Hughes; Klaus-Peter Jungmann; Ic Lane; Yi-Wei Liu; D. M. Lucas; Y Matyugin; J. Merkel; Gz Putlitz; S. Reinhard; P G H Sandars; Robin Santra; Pv Schmidt; C. A. Scott; Wt Toner; Michael Towrie; K Trager; Lorenz Willmann; Yakhontov
The 1s-2s interval has been measured in the muonium (&mgr;(+)e(-)) atom by Doppler-free two-photon pulsed laser spectroscopy. The frequency separation of the states was determined to be 2 455 528 941.0(9.8) MHz, in good agreement with quantum electrodynamics. The result may be interpreted as a measurement of the muon-electron charge ratio as -1-1.1(2.1)x10(-9). We expect significantly higher accuracy at future high flux muon sources and from cw laser technology.
Physical Review D | 2000
H. N. Brown; G. Bunce; R. M. Carey; P. Cushman; G. T. Danby; P. T. Debevec; H Deng; Sk Dhawan; V. P. Druzhinin; L. Duong; W. Earle; E. Efstathiadis; G. V. Fedotovich; F. J. M. Farley; S. Giron; F. Gray; M. Grosse-Perdekamp; A. Grossmann; Ulrich Haeberlen; M. F. Hare; E. Hazen; David W. Hertzog; Vw Hughes; M. Iwasaki; Klaus-Peter Jungmann; D Kawall; M. Kawamura; B. I. Khazin; J. Kindem; F. Krienen
A new measurement of the positive muons anomalous magnetic moment has been made at the Brookhaven Alternating Gradient Synchrotron using the direct injection of polarized muons into the superferric storage ring. The angular frequency difference omega (a) between the angular spin precession frequency omega (s) and the angular orbital frequency omega (c) is measured as well as the free proton MMR frequency omega (p). These determine R = omega (a)/omega (p) = 3.707 201(19) x 10(-3). With mu (mu)/mu (p) = 3.183 345 39(10) this gives a(mu+) = 11 659 191(59) x 10-(10) (+/-5 ppm), in good agreement with the previous CERN and BNL measurements for mu (+) and mu (-), and with the standard model prediction.
Physical Review Letters | 2001
Vernon W. Hughes; M. Grosse Perdekamp; D. Kawall; Weilin Liu; Klaus-Peter Jungmann; G. zu Putlitz
Following a suggestion of Kostelecký et al. we have evaluated a test of CPT and Lorentz invariance from the microwave spectrosopy of muonium. Precise measurements have been reported for the transition frequencies v 12 and v 34 for ground state muonium in a magnetic field H of 1.7 T, both of which involve principally muon spin flip. These frequencies depend on both the hyperfine interaction and Zeeman effect. Hamiltonian terms beyond the standard model which violate CPT and Lorentz invariance would contribute shifts δv 12 and δv 34. The nonstandard theory indicates that v 12 and v 34 should oscillate with the earth’s sidereal frequency and that δv 12 and δv 34 would be anticorrelated. We find no time dependence in v 12—v 34 at the level of 20 Hz, which is used to set an upper limit on the size of CPT and Lorentz violating parameters.
arXiv: High Energy Physics - Experiment | 2003
Yannis K. Semertzidis; M. Aoki; M. Auzinsh; V. Balakin; A. Bazhan; G. W. Bennett; R. M. Carey; P. Cushman; P. T. Debevec; A. Dudnikov; F. J. M. Farley; David W. Hertzog; M. Iwasaki; Klaus-Peter Jungmann; D. Kawall; B. I. Khazin; I. B. Khriplovich; B. Kirk; Y. Kuno; D. M. Lazarus; L. B. Leipuner; V. Logashenko; K. R. Lynch; W. J. Marciano; R. McNabb; W. Meng; J. P. Miller; W. M. Morse; C. J. G. Onderwater; Y. Orlov
In this paper a new method is presented for particles in storage rings which could reach a statistical sensitivity of 10−27 e⋅cm for the deuteron EDM. This implies an improvement of two orders of magnitude over the present best limits on the T‐odd nuclear forces ξ parameter.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2001
G. T. Danby; L. Addessi; Z. Armoza; J. Benante; H. N. Brown; G. Bunce; J. Cottingham; J. Cullen; J. Geller; H. Hseuh; J. W. Jackson; L. Jia; S. Kochis; D. Koniczny; R.C. Larsen; Y. Y. Lee; M. Mapes; R. E. Meier; W. Meng; W. M. Morse; M. O'Toole; C. Pai; I. Polk; R. Prigl; Yannis K. Semertzidis; R. Shutt; L. Snydstrup; A. Soukas; T. Tallerico; F. Toldo
Abstract The muon g-2 experiment at Brookhaven National Laboratory has the goal of determining the muon anomalous g-value a μ (=(g−2)/2) to the very high precision of 0.35 parts per million and thus requires a storage ring magnet with great stability and homogeniety. A superferric storage ring with a radius of 7.11 m and a magnetic field of 1.45 T has been constructed in which the field quality is largely determined by the iron, and the excitation is provided by superconducting coils operating at a current of 5200 A. The storage ring has been constructed with maximum attention to azimuthal symmetry and to tight mechanical tolerances and with many features to allow obtaining a homogenous magnetic field. The fabrication of the storage ring, its cryogenics and quench protection systems, and its initial testing and operation are described.
Physical Review A | 2009
S. De; U. Dammalapati; Klaus-Peter Jungmann; Lorenz Willmann
Laser cooling and trapping of the heavy alkaline-earth-metal element barium has been achieved based on the strong 6s(2) (1)S(0)-6s6p (1)P(1) transition. The excited state decays to a large fraction into metastable D states. Two schemes were implemented where three additional laser-driven transitions provide closed cooling cycles. This results in a fraction of 50(20)% of the trapped atoms in one of the metastable states. A total efficiency of 0.4(1)x10(-2) for slowing a thermal atomic beam and capturing atoms into a magneto-optical trap was obtained. Trap lifetimes of more than 1.5 s were observed. They are shortened at high laser intensities by three photon photoionization losses. The developed scheme can be transferred to other systems with large leakage from the cooling transition, such as Ra which is interesting for sensitive fundamental symmetry research.
