Search results for "particle trap"

showing 3 items of 3 documents

Towards a test of the weak equivalence principle of gravity using anti-hydrogen at CERN

2016

International audience; The aim of the GBAR (Gravitational Behavior of Antimatter at Rest) experiment is to measure the free fall acceleration of an antihydrogen atom, in the terrestrial gravitational field at CERN and therefore test the Weak Equivalence Principle with antimatter. The aim is to measure the local gravity with a 1% uncertainty which can be reduced to few parts of 10-3.

Free fallGravity (chemistry)Particle physicsPhysics::General PhysicsAntimatterCERN LabGravityacceleration measurementterrestrial gravitational fieldfree fall acceleration01 natural sciencesantihydrogen: accelerationweak equivalence principle010305 fluids & plasmasparticle trapsAtomic measurementsGravitationGeneral Relativity and Quantum Cosmologyhydrogen: ionGravitational fieldLaser transitionsAtom (measure theory)0103 physical sciencesPhysics::Atomic and Molecular Clusters[PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex]010306 general physicsAntihydrogenantihydrogen atomPhysicsIonsatomProductionEquivalence principle (geometric)laserequivalence principleAntimatter[PHYS.GRQC]Physics [physics]/General Relativity and Quantum Cosmology [gr-qc]talk: Ottawa 2016/07/10gravitation: localhydrogen ionsCoolingGravitation
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3D-Printable Model of a Particle Trap: Development and Use in the Physics Classroom

2019

Quadrupole ion traps are modern and versatile research tools used in mass spectrometers, in atomic frequency and time standards, in trapped ion quantum computing research, and for trapping anti-hydrogen ions at CERN. Despite their educational potential, quadrupole ion traps are seldom introduced into the physics classroom not least because commercial quadrupole ion traps appropriate for classroom use are expensive and difficult to set up. We present an open hardware 3D-printable quadrupole ion trap suitable for the classroom, which is capable of trapping lycopodium spores. We also provide student worksheets developed in an iterative design process, which can guide students while discovering…

PhysicsCondensed Matter::Quantum GasesLarge Hadron ColliderIterative designlcsh:Engineering machinery tools and implementsPhysics Education; Quadrupole Ion Trap; Paul Trap; Particle Trap; 3D Printable3d printableparticle trapPhysics::Physics EducationMass spectrometrylcsh:Engineering designEngineering physicsIonpaul trapTrap (computing)lcsh:TA174Quadrupolephysics educationIon trapPhysics::Atomic PhysicsQuadrupole ion traplcsh:TA213-215quadrupole ion trapEducation and Outreach
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Mass Measurement on the rp-Process Waiting Point 72Kr

2004

The mass of one of the three major waiting points in the astrophysical rp process $^{72}$Kr was measured for the first time with the Penning trap mass spectrometer ISOLTRAP. The measurement yielded a relative mass uncertainty of $\deltam/m = 1.2\times 10–7 (\deltam$ = 8 keV). $^{73,74}$Kr, also needed for astrophysical calculations, were measured with more than 1 order of magnitude improved accuracy. We use the ISOLTRAP masses of $^{72–74}$Kr to reanalyze the role of $^{72}$Kr (T$_{1/2}$ = 17.2 s) in the rp process during x-ray bursts and conclude that $^{72}$Kr is a strong waiting point delaying the burst duration with at least 80\% of its $\beta$-decay half-life.

PhysicsNuclear and High Energy PhysicsLarge Hadron Collider26.30.+k 21.10.Dr 27.50.+e 32.10.Bi010308 nuclear & particles physicsHadronrp-process[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]Mass spectrometryPenning trap01 natural sciencesISOLTRAPnuclei with mass number 59 to 89particle trapsNuclear physicsnuclear massNucleosynthesis0103 physical sciencesNuclear fusionNuclear Physics - Experimentnucleon-nucleus reactions010306 general physicsNuclear Experimentbeta-decayNuclear Physics
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