Search results for "Electron rest mass"

showing 6 items of 6 documents

New determination of the electron's mass.

2001

A new independent value for the electron's mass in units of the atomic mass unit is presented, ${m}_{e}\phantom{\rule{0ex}{0ex}}=\phantom{\rule{0ex}{0ex}}0.0005485799092(4)\mathrm{u}$. The value is obtained from our recent measurement of the $g$ factor of the electron in ${}^{12}{\mathrm{C}}^{5+}$ in combination with the most recent quantum electrodynamical (QED) predictions. In the QED corrections, terms of order ${\ensuremath{\alpha}}^{2}$ were included by a perturbation expansion in $Z\ensuremath{\alpha}$. Our total precision is three times better than that of the accepted value for the electron's mass.

PhysicsAntiparticleAtomic mass constantLandé g-factorElectron rest massGeneral Physics and AstronomyOrder (ring theory)Elementary particleAtomic mass unitAtomic physicsHyperfine structurePhysical review letters
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High-precision measurement of the atomic mass of the electron

2014

A very precise measurement of the magnetic moment of a single electron bound to a carbon nucleus, combined with a state-of-the-art calculation in the framework of bound-state quantum electrodynamics, gives a new value of the atomic mass of the electron that is more precise than the currently accepted one by a factor of 13. The atomic mass of the electron is a key parameter for fundamental physics. A precise determination is a challenge because the mass is so low. Sven Sturm and colleagues report on a new determination of the electron's mass in atomic units. The authors measured the magnetic moment of a single electron bound to a reference ion (a bare nucleus of carbon-12). The results were …

PhysicsMultidisciplinaryMass-to-charge ratioAtomic Physics (physics.atom-ph)Research group Z. Harman – Division C. H. KeitelGravitational coupling constantElectron rest massFOS: Physical sciencesElectron01 natural sciencesAtomic unitsAtomic massPhysics - Atomic Physics010305 fluids & plasmasRydberg constantAtomic mass constant0103 physical sciencesPräzisionsexperimente - Abteilung BlaumAtomic physics010306 general physicsNature
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A Possible New Value for the Electron Mass from g-Factor Measurements on Hydrogen-Like Ions

2001

The mass of the electron in atomic units (m e) represents the largest error contribution in an experiment to determine the g-factor of the electron bound in hydrogen-like carbon. Recent progress in the calculation reduces the uncertainty of the theoretical value to such a low value that m e can be determined from a comparison of experimental and theoretical g-factors. The present preliminary value of the electron mass agrees with the accepted value but reduces the uncertainty by about a factor 2.

HydrogenChemistryElectron captureElectron rest masschemistry.chemical_elementElectronAtomic physicsValue (mathematics)Atomic unitsIonAccepted and experimental value
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Direct Measurement of the Mass Difference ofHo163andDy163Solves theQ-Value Puzzle for the Neutrino Mass Determination

2015

The atomic mass difference of (163)Ho and (163)Dy has been directly measured with the Penning-trap mass spectrometer SHIPTRAP applying the novel phase-imaging ion-cyclotron-resonance technique. Our measurement has solved the long-standing problem of large discrepancies in the Q value of the electron capture in (163)Ho determined by different techniques. Our measured mass difference shifts the current Q value of 2555(16) eV evaluated in the Atomic Mass Evaluation 2012 [G. Audi et al., Chin. Phys. C 36, 1157 (2012)] by more than 7σ to 2833(30(stat))(15(sys)) eV/c(2). With the new mass difference it will be possible, e.g., to reach in the first phase of the ECHo experiment a statistical sensit…

Physics010308 nuclear & particles physicsElectron captureQ valueElectron rest massGeneral Physics and AstronomyMass spectrometry7. Clean energy01 natural sciencesBeta decayAtomic massNuclear physicsAtomic mass constant0103 physical sciencesNeutrino010306 general physicsPhysical Review Letters
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Precision studies in traps: Measurement of fundamental constants and tests of fundamental theories

2003

Experiments on single atomic particles confined in Penning ion traps have contributed significantly to the improvements of fundamental constants and to tests of the theory of Quantum Electrodynamics for free and bound electrons. The most precise value of the fine structure constant as well as the electron mass have been derived from trap experiments. Numerous atomic masses of interest for fundamental questions have been determined with precisions of 10 � 9 or below. Further progress is envisaged in the near future.

Condensed Matter::Quantum GasesPhysicsNuclear and High Energy PhysicsElectron rest massFine-structure constantElectronPenning trapAtomic massIonPhysics::Atomic PhysicsSubatomic particleIon trapAtomic physicsInstrumentationNuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms
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Positron Production In Heavy-Ion Collisions

1985

Atomic systems with a nuclear charge Z much greater than 100 exhibit a number of unique features not otherwise found in nature. Two characteristic properties are illustrated in Figs. 1 and 2. In Fig. 1 we have plotted the binding energy of a K-shell electron around hypothetical nuclei up to Z ≈ 200. For Z > 150 the binding energy exceeds the rest energy m e c 2 of the electron; i.e., adding the electron to the nucleus actually diminishes the total mass of the system. At the critical charge Z c ≈ 170–175 the binding energy reaches twice the electron rest mass, the threshold for spontaneous creation of an electron-positron pair. As has been discussed extensively in the literature (Pieper and …

PhysicsPhase transitionBinding energyElectron rest massElectron shellCharge (physics)ElectronAtomic physicsGround stateEffective nuclear charge
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