Search results for "ANTIHYDROGEN"

showing 10 items of 31 documents

Electron-cooled accumulation of 4 × 109positrons for production and storage of antihydrogen atoms

2016

Four billion positrons (e+) are accumulated in a Penning–Ioffe trap apparatus at 1.2 K and <6 × 10−17 Torr. This is the largest number of positrons ever held in a Penning trap. The e+ are cooled by collisions with trapped electrons (e−) in this first demonstration of using e− for efficient loading of e+ into a Penning trap. The combined low temperature and vacuum pressure provide an environment suitable for antihydrogen () production, and long antimatter storage times, sufficient for high-precision tests of antimatter gravity and of CPT.

Condensed Matter::Quantum GasesPhysicsPhysics::General PhysicsAntiparticleAnnihilationPlasmaElectronCondensed Matter PhysicsPenning trap01 natural sciencesAtomic and Molecular Physics and Optics010305 fluids & plasmasNuclear physicsTorrAntimatter0103 physical sciencesPhysics::Atomic and Molecular ClustersPhysics::Atomic PhysicsAtomic physics010306 general physicsAntihydrogenJournal of Physics B: Atomic, Molecular and Optical Physics
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Pumped helium system for cooling positron and electron traps to 1.2 K

2011

Abstract Extremely precise tests of fundamental particle symmetries should be possible via laser spectroscopy of trapped antihydrogen ( H ¯ ) atoms. H ¯ atoms that can be trapped must have an energy in temperature units that is below 0.5 K—the energy depth of the deepest magnetic traps that can currently be constructed with high currents and superconducting technology. The number of atoms in a Boltzmann distribution with energies lower than this trap depth depends sharply upon the temperature of the thermal distribution. For example, ten times more atoms with energies low enough to be trapped are in a thermal distribution at a temperature of 1.2 K than for a temperature of 4.2 K. To date, H…

Condensed Matter::Quantum GasesSuperconductivityPhysicsantihydrogenNuclear and High Energy Physicsliquid heliumLiquid heliumPenning trapchemistry.chemical_elementElectronAtmospheric temperature rangePenning traplaw.inventionchemistrylawAntimatterantiprotonrefrigeratorPhysics::Atomic PhysicsAtomic physicsAntihydrogenInstrumentationHelium
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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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Towards the european strategy for particle physics: The briefing book

2007

This document was prepared as part of the briefing material for the Workshop of the CERN Council Strategy Group, held in DESY Zeuthen from 2nd to 6th May 2006. It gives an overview of the physics issues and of the technological challenges that will shape the future of the field, and incorporates material presented and discussed during the Symposium on the European Strategy for Particle Physics, held in Orsay from 30th January to 2nd February 2006, reflecting the various opinions of the European community as recorded in written submissions to the Strategy Group and in the discussions at the Symposium.

High Energy Physics - TheoryParticle physicsANTIHYDROGENPhysics and Astronomy (miscellaneous)European communityNEUTRINO OSCILLATIONSFOS: Physical sciencesddc:500.2ACCELERATION01 natural sciencesELECTRON-BEAMSHigh Energy Physics - ExperimentENERGYHigh Energy Physics - Experiment (hep-ex)High Energy Physics - Phenomenology (hep-ph)0103 physical sciences[PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex]FIELD010306 general physicsEngineering (miscellaneous)Particle Physics - PhenomenologyPhysicsLarge Hadron Collider010308 nuclear & particles physicshep-exLHC LUMINOSITY UPGRADE[PHYS.HTHE]Physics [physics]/High Energy Physics - Theory [hep-th]Field (Bourdieu)hep-thFísicaDESYhep-phHigh Energy Physics - PhenomenologyHigh Energy Physics - Theory (hep-th)LASER-PULSES[PHYS.HPHE]Physics [physics]/High Energy Physics - Phenomenology [hep-ph]DOUBLE-BETA DECAY
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A pulsed high-voltage decelerator system to deliver low-energy antiprotons

2021

International audience; The GBAR (Gravitational Behavior of Antihydrogen at Rest) experiment at CERN requires efficient deceleration of 100 keV antiprotons provided by the new ELENA synchrotron ring to synthesize antihydrogen. This is accomplished using electrostatic deceleration optics and a drift tube that is designed to switch from -99 kV to ground when the antiproton bunch is inside – essentially a charged particle “elevator” – producing a 1 keV pulse. We describe the simulation, design, construction and successful testing of the decelerator device at -92 kV on-line with antiprotons from ELENA.

Nuclear and High Energy PhysicsDrift tubeGeneral RelativityIon-optic simulationsCERN Labdrift tubeAstrophysics::High Energy Astrophysical Phenomena[PHYS.PHYS.PHYS-ACC-PH]Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph]Charged-particle opticsfabrication7. Clean energy01 natural sciencesanti-p: decelerationlaw.inventionNuclear physicslaw0103 physical sciencessynchrotronPhysics::Atomic Physics010306 general physicsAntihydrogennumerical calculationsInstrumentationaccelerator: designPhysicsantihydrogenLarge Hadron Collider010308 nuclear & particles physicsHigh voltageCharged particleSynchrotron[PHYS.PHYS.PHYS-GEN-PH]Physics [physics]/Physics [physics]/General Physics [physics.gen-ph]Pulse (physics)beam opticsAntiprotonPhysics::Accelerator Physics
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Studies on Antihydrogen Atoms with the ATRAP Experiment at CERN

2013

The CPT theorem predicts the same properties of matter and antimatter, however, in the nearby Universe, we observe a huge imbalance of matter and antimatter. Therefore, it is intriguing to measure the properties of particles and antiparticles in order to contribute to an explanation of this phenomena. In this article, we will describe the experimental efforts of the ATRAP Collaboration in order to test the CPT theorem using antihydrogen atoms.

Nuclear physicsPhysics::Popular PhysicsPhysics::General PhysicsEngineeringLarge Hadron Colliderbusiness.industryPhysics::Atomic and Molecular ClustersGeneral Physics and AstronomyHigh Energy Physics::ExperimentAntihydrogenbusinessActa Physica Polonica B Proceedings Supplement
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Polarization analysis of $\bar{p}$ produced in pA collisions

2019

A quite simple procedure for the generation of a polarized antiproton beam could be worked out if antiprotons are produced with some polarization. In order to investigate this possibility measurements of the polarization of produced antiprotons have been started at a CERN/PS test beam. The polarization will be determined from the asymmetry of the elastic antiproton scattering at a liquid hydrogen target in the CNI region for which the analyzing power is well known. The data are under analysis and an additional measurement is done in 2018. Details on the experiment and the ongoing data analysis will be given.

PhysicsAntiparticle010308 nuclear & particles physicsPhysicsQC1-999Polarization (waves)01 natural sciences7. Clean energyNuclear physicsAntiproton beamAntiproton0103 physical sciencesPhysics::Accelerator Physicsddc:530High Energy Physics::ExperimentPhysics::Atomic Physics010306 general physicsAntihydrogenNuclear Experiment
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ATRAP antihydrogen experiments

2007

Antihydrogen (Hbar) was first produced at CERN in 1996. Over the past decade our ATRAP collaboration has made massive progress toward our goal of producing large numbers of cold Hbar atoms that will be captured in a magnetic gradient trap for precise comparison between the atomic spectra of matter and antimatter. The AD at CERN provides bunches of 3 × 107 low energy Pbars every 100 seconds. We capture and cool to 4 K, 0.1% of these in a cryogenic Penning trap. By stacking many bunches we are able to do experiments with 3 × 105 Pbars. ∼100 e+/sec from a 22Na radioactive source are captured and cooled in the trap, with 5 × 106 available experiments.We have developed 2 ways to make Hbar from t…

PhysicsAntiparticleCondensed Matter PhysicsPenning trapNuclear physicssymbols.namesakeAntiprotonLaser coolingAntimatterRydberg formulasymbolsPhysics::Atomic PhysicsAtomic physicsNeutral particleAntihydrogenphysica status solidi c
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Centrifugal Separation of Antiprotons and Electrons

2010

Centrifugal separation of antiprotons and electrons is observed, the first such demonstration with particles that cannot be laser cooled or optically imaged. The spatial separation takes place during the electron cooling of trapped antiprotons, the only method available to produce cryogenic antiprotons for precision tests of fundamental symmetries and for cold antihydrogen studies. The centrifugal separation suggests a new approach for isolating low energy antiprotons and for producing a controlled mixture of antiprotons and electrons.

PhysicsAntiparticleGeneral Physics and AstronomyPlasmaElectronJlaw.inventionNuclear physicsAntiprotonlawAntimatterddc:550Physics::Accelerator PhysicsHigh Energy Physics::ExperimentPhysics::Atomic PhysicsAtomic physicsNuclear ExperimentAntihydrogenLeptonElectron coolingPhysical Review Letters
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Preparing single ultra-cold antihydrogen atoms for free-fall in GBAR

2014

We discuss an experimental approach allowing to prepare antihydrogen atoms for the GBAR experiment. We study the feasibility of all necessary experimental steps: The capture of incoming $\bar{\rm H}^{+}$ ions at keV energies in a deep linear RF trap, sympathetic cooling by laser cooled Be+ ions, transfer to a miniaturized trap and Raman sideband cooling of an ion pair to the motional ground state, and further reducing the momentum of the wavepacket by adiabatic opening of the trap. For each step, we point out the experimental challenges and discuss the efficiency and characteristic times, showing that capture and cooling are possible within a few seconds. We discuss an experimental approach…

PhysicsCondensed Matter::Quantum GasesSympathetic coolingOther Fields of Physics7. Clean energyphysics.atom-phIonMomentumquant-ph13. Climate actionAntimatterPhysics::Atomic PhysicsAtomic physicsAdiabatic processGround stateAntihydrogenGeneral Theoretical PhysicsBar (unit)
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