Search results for "Penn"

showing 10 items of 568 documents

Penning-trap mass spectrometry and mean-field study of nuclear shape coexistence in the neutron-deficient lead region

2017

We present a study of nuclear shape coexistence in the region of neutron-deficient lead isotopes. The midshell gold isotopes 180,185,188,190Au (Z=79), the two long-lived nuclear states in 197At (Z=85), and the neutron-rich nuclide 219At were produced by the ISOLDE facility at CERN and their masses were determined with the high-precision Penning-trap mass spectrometer ISOLTRAP. The studied gold isotopes address the trend of binding energies in a region of the nuclear chart where the nuclear charge radii show pronounced discontinuities. Significant deviations from the atomic-mass evaluation were found for 188,190Au. The new trend of two-neutron separation energies is smoother, although it doe…

PhysicsIsotope010308 nuclear & particles physicsBinding energyNuclear Theory[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]Penning trap01 natural sciencesISOLTRAPEffective nuclear chargeNuclear physics0103 physical sciencesNeutronIsotopes of goldNuclide010306 general physicsNuclear Experiment
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Restoration of theN=82Shell Gap from Direct Mass Measurements ofSn132,134

2008

A high-precision direct Penning trap mass measurement has revealed a 0.5-MeV deviation of the binding energy of (134)Sn from the currently accepted value. The corrected mass assignment of this neutron-rich nuclide restores the neutron-shell gap at N=82, previously considered to be a case of "shell quenching." In fact, the new shell gap value for the short-lived (132)Sn is larger than that of the doubly magic (48)Ca which is stable. The N=82 shell gap has considerable impact on fission recycling during the r process. More generally, the new finding has important consequences for microscopic mean-field theories which systematically deviate from the measured binding energies of closed-shell nu…

PhysicsIsotope010308 nuclear & particles physicsFissionNuclear TheoryBinding energyGeneral Physics and AstronomyMass spectrometryPenning trap01 natural sciencesISOLTRAP0103 physical sciencesPhysics::Atomic and Molecular Clustersr-processNuclideAtomic physicsNuclear Experiment010306 general physicsPhysical Review Letters
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Mass Measurements of Very Neutron-Deficient Mo and Tc Isotopes and Their Impact on rp Process Nucleosynthesis

2011

The masses of ten proton-rich nuclides, including the N=Z+1 nuclides 85-Mo and 87-Tc, were measured with the Penning trap mass spectrometer SHIPTRAP. Compared to the Atomic Mass Evaluation 2003 a systematic shift of the mass surface by up to 1.6 MeV is observed causing significant abundance changes of the ashes of astrophysical X-ray bursts. Surprisingly low alpha-separation energies for neutron-deficient Mo and Tc are found, making the formation of a ZrNb cycle in the rp process possible. Such a cycle would impose an upper temperature limit for the synthesis of elements beyond Nb in the rp process.

PhysicsIsotope010308 nuclear & particles physicsGeneral Physics and AstronomyFOS: Physical sciencesrp-process[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]Penning trapMass spectrometry7. Clean energy01 natural sciencesAtomic massNuclear physics13. Climate actionNucleosynthesis0103 physical sciencesNeutronNuclideNuclear Experiment (nucl-ex)010306 general physicsNuclear Experiment
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Charge breeding rare isotopes for high precision mass measurements: challenges and opportunities

2013

Ion charge breeding for Penning-trap mass spectrometry has been established as providing a precision increase that scales linearly with the charge state of the ion. Fast and efficient charge breeding is a precondition for the application of this approach to rare isotopes. However, in view of low yields and short half-lives the precision boost is partly compromised by unavoidable ion losses inherent to the charge breeding process. The mass spectrometer TRIUMFs ion trap for atomic and nuclear science is pioneering this field by coupling a Penning trap and an electron beam ion trap to the rare-isotope beam facility ISAC at TRIUMF. Here we present simulations that calculate and maximize the eff…

PhysicsIsotopeCharge (physics)Condensed Matter PhysicsPenning trapMass spectrometryAtomic and Molecular Physics and OpticsIonNuclear physicsPhysics::Plasma PhysicsPhysics::Atomic PhysicsIon trapNuclideAtomic physicsNuclear ExperimentMathematical PhysicsElectron beam ion trapPhysica Scripta
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Mass Determination of Francium and Radium Isotopes by a Penning Trap Mass Spectrometer

1992

Abstract A tandem Penning trap mass spectrometer is used for mass measurement of radioactive isotopes produced at the on-line isotope separator ISOLDE/CERN. The mass is determined directly and with high accuracy by measuring the cyclotron frequency of the stored ions. Measurements were performed on 209 210 211 212 221 222Fr and 226 230Ra. A resolving power of 5 × 105 was used and an accuracy of 1·8 × 10−7 has been achieved.

PhysicsIsotopeCyclotronchemistry.chemical_elementMass spectrometryPenning trapISOLTRAPAtomic and Molecular Physics and OpticsFranciumlaw.inventionRadiumNuclear physicschemistrylawNuclear Physics - ExperimentHybrid mass spectrometerJournal of Modern Optics
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First Precision Mass Measurements of Refractory Fission Fragments

2005

Atomic masses of 95-100Sr, 98-105Zr, and [corrected] 102-110Mo and have been measured with a precision of 10 keV employing a Penning trap setup at the IGISOL facility. Masses of 104,105Zr and 109,110Mo are measured for the first time. Our improved results indicate significant deviations from the previously published values deduced from beta end point measurements. The most neutron-rich studied isotopes are found to be significantly less bound (1 MeV) compared to the 2003 atomic mass evaluation. A strong correlation between nuclear deformation and the binding energy is observed in the two-neutron separation energy in all studied isotope chains.

PhysicsIsotopeFissionBeta (plasma physics)Binding energyGeneral Physics and AstronomyPhysics::Atomic PhysicsAtomic physicsDeformation (meteorology)Nuclear ExperimentPenning trapMass spectrometryAtomic massPhysical Review Letters
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Recent Upgrades of the SHIPTRAP Setup: On the Finish Line Towards Direct Mass Spectroscopy of Superheavy Elements

2016

With the Penning-trap mass spectrometer SHIPTRAP at GSI, Darmstadt, it is possible to investigate exotic nuclei in the region of the heaviest elements. Few years ago, challenging experiments led to the direct measurements of the masses of neutron-deficient isotopes with Z = 102,103 around N = 152. Thanks to recent advances in cooling and ion-manipulation techniques, a major technical upgrade of the setup has been recently accomplished to boost its efficiency. At present, the gap to reach more rare and shorter-lived species at the limits of the nuclear landscape has been narrowed. ispartof: pages:423-429 ispartof: Acta Physica Polonica B vol:48 issue:3 pages:423-429 ispartof: location:Zakopa…

PhysicsIsotopePenning trapGeneral Physics and AstronomyFinish lineSuperheavy Elements[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]Accelerator Physics and InstrumentationPenning trapMass spectrometry01 natural sciences7. Clean energy010305 fluids & plasmasNuclear physicsUpgrade0103 physical sciences[PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det]010306 general physics
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Hyperfine structure andg-factor measurements in ion traps

1995

We report about measurements on ground-state hyperfine splitting constants of stable Eu+ isotopes in radio frequency ion traps and experiments on the electronicg-factor of Ba+ in a Penning trap. From the precision of both measurements, which ranges between 3·10−6 and 5·10−7, we conclude that precise determination of the differential Bohr-Weisskopf effect in chains of isotopes will be possible in the near future.

PhysicsIsotopePhysics::Atomic PhysicsRadio frequencyAtomic physicsCondensed Matter PhysicsPenning trapHyperfine structureMathematical PhysicsAtomic and Molecular Physics and OpticsIonPhysica Scripta
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Direct determination of the mass of28Si as a contribution to a new definition of the kilogram

1993

The mass of 28Si has been determined to be m(28Si) = 27.976 926 57(30) u by comparing the cyclotron frequencies of the singly charged ions 12C+, 12C+3 and 28Si+ in a Penning trap mass spectrometer. The experimental technique and the setup are described. The obtained accuracy as well as possible improvements are discussed. Our measurements are related to current efforts to base the kilogram on atomic properties by using an almost perfect single crystal of silicon.

PhysicsKilogramCyclotronCondensed Matter PhysicsPenning trapMass spectrometryAtomic and Molecular Physics and OpticsAtomic massIonlaw.inventionlawIsotopes of siliconAtomic physicsSingle crystalMathematical PhysicsPhysica Scripta
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2008

Penning traps offer unique possibilities for storing, manipulating and investigating charged particles with high sensitivity and accuracy. The widespread applications of Penning traps in physics and chemistry comprise e.g. mass spectrometry, laser spectroscopy, measurements of electronic and nuclear magnetic moments, chemical sample analysis and reaction studies. We have developed a method, based on the Green's function approach, which allows for the analytical calculation of the electrostatic properties of a Penning trap with arbitrary electrodes. The ansatz features an extension of Dirichlet's problem to nontrivial geometries and leads to an analytical solution of the Laplace equation. As…

PhysicsLaplace's equationMagnetic momentProtonAnharmonicityGeneral Physics and AstronomyPhysics::Atomic PhysicsIon trapAtomic physicsPenning trapCharged particleAnsatzNew Journal of Physics
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