Your search keyword '"A. Povilus"' showing total 28 results

1. Limit on the electric charge of antihydrogen

Author

D. P. van der Werf, A. Little, M. E. Hayden, K. Olchanski, T. D. Tharp, Petteri Pusa, Joel Fajans, S. Menary, Z. Vendeiro, A. E. Charman, A. Capra, William Bertsche, M. D. Ashkezari, Leonid Kurchaninov, Marcelo Baquero-Ruiz, Andrea Gutierrez, Chukman So, Svante Jonsell, M. Charlton, Andrey Zhmoginov, S. C. Napoli, Eoin Butler, E. Sarid, Stefan Eriksson, P. J. Nolan, A. Olin, Jonathan Wurtele, D. M. Silveira, D. R. Gill, C. L. Cesar, J. S. Hangst, C. Amole, Francis Robicheaux, M. C. Fujiwara, W. N. Hardy, J. T. K. McKenna, T. Friesen, C. A. Isaac, Robert Thompson, and A. Povilus

Subjects

0301 basic medicine, Nuclear and High Energy Physics, Silicon detector, Atomic Physics (physics.atom-ph), CPT symmetry, Other Fields of Physics, FOS: Physical sciences, 01 natural sciences, Electric charge, Physics - Atomic Physics, Fundamental symmetries, 03 medical and health sciences, Electric field, 0103 physical sciences, Atom, Nuclear Physics - Experiment, Quantum anomaly, Physics::Atomic Physics, Physical and Theoretical Chemistry, 010306 general physics, Antihydrogen, Physics, Annihilation, High Energy Physics::Phenomenology, Charge (physics), Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Position sensitive detector, 030104 developmental biology, Atom trapping, Production (computer science), Electric neutrality, CPT, Atomic physics

Abstract

The ALPHA collaboration has successfully demonstrated the production and the confinement of cold antihydrogen, $\overline{\mathrm{H}}$. An analysis of trapping data allowed a stringent limit to be placed on the electric charge of the simplest antiatom. Charge neutrality of matter is known to a very high precision, hence a neutrality limit of $\overline{\mathrm{H}}$ provides a test of CPT invariance. The experimental technique is based on the measurement of the deflection of putatively charged $\overline{\mathrm{H}}$ in an electric field. The tendency for trapped $\overline{\mathrm{H}}$ atoms to be displaced by electrostatic fields is measured and compared to the results of a detailed simulation of $\overline{\mathrm{H}}$ dynamics in the trap. An extensive survey of the systematic errors is performed, with particular attention to those due to the silicon vertex detector, which is the device used to determine the $\overline{\mathrm{H}}$ annihilation position. The limit obtained on the charge of the $\overline{\mathrm{H}}$ atom is \mbox{$ Q = (-1.3\pm1.8\pm0.4)\times10^{-8}$}, representing the first precision measurement with $\overline{\mathrm{H}}$., Comment: 5 pages, 3 figures

Published

2021

2. Electron Plasmas Cooled by Cyclotron-Cavity Resonance

Author

Isaac Martens, N. D. DeTal, L. T. Evans, N. Evetts, Eric Hunter, Xiao Wang, Chukman So, Joel Fajans, Walter Hardy, S. Shanman, Jonathan Wurtele, A. Povilus, and Francis Robicheaux

Subjects

General Physics, Materials science, Cyclotron, General Physics and Astronomy, FOS: Physical sciences, Electron, 01 natural sciences, Electron cyclotron resonance, Mathematical Sciences, 010305 fluids & plasmas, law.invention, Standing wave, Engineering, law, Physics::Plasma Physics, Electromagnetic cavity, physics.plasm-ph, 0103 physical sciences, Physics::Atomic Physics, 010306 general physics, Plasma, equipment and supplies, Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), Physical Sciences, Physics::Space Physics, Electromagnetic electron wave, Atomic physics

Abstract

We observe that high-Q electromagnetic cavity resonances increase the cyclotron cooling rate of pure electron plasmas held in a Penning-Malmberg trap when the electron cyclotron frequency, controlled by tuning the magnetic field, matches the frequency of standing wave modes in the cavity. For certain modes and trapping configurations, this can increase the cooling rate by factors of ten or more. In this paper, we investigate the variation of the cooling rate and equilibrium plasma temperatures over a wide range of parameters, including the plasma density, plasma position, electron number, and magnetic field., Comment: 5 pages, 5 figures

Published

2016

3. Progress towards microwave spectroscopy of trapped antihydrogen

Author

Yasunori Yamazaki, Ryugo S. Hayano, Lenoid Kurchaninov, A. Povilus, A. Olin, Richard Hydomako, K. Olchanski, Joel Fajans, M. C. Fujiwara, Niels Madsen, M. D. Ashkezari, Robert Thompson, Adam Deller, J. S. Hangst, Wil Bertsche, M. Charlton, Eoin Butler, T. Friesen, D. M. Silveira, Dirk Peter van der Werf, Stefan Eriksson, James William Storey, Jonathan Wurtele, E. Sarid, P. J. Nolan, Francis Robicheaux, P. D. Bowe, Michael E. Hayden, Walter Hardy, S. Menary, Steve Chapman, C. L. Cesar, Gorm Bruun Andresen, Chukman So, Dave R. Gill, Marcelo Baquero-Ruiz, Andrea Gutierrez, Petteri Pusa, A. J. Humphries, and Svante Jonsell

Subjects

Physics, Nuclear and High Energy Physics, Hydrogen, CPT symmetry, chemistry.chemical_element, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Nuclear physics, chemistry, Atom, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Rotational spectroscopy, Physical and Theoretical Chemistry, Atomic physics, Antihydrogen, Hyperfine structure, Microwave

Abstract

Precision comparisons of hyperfine intervals in atomic hydrogen and antihydrogen are expected to yield experimental tests of the CPT theorem. The CERN-based ALPHA collaboration has initiated a program of study focused on microwave spectroscopy of trapped ground-state antihydrogen atoms. This paper outlines some of the proposed experiments, and summarizes measurements that characterize microwave fields that have been injected into the ALPHA apparatus.

Published

2011

4. Trapped antihydrogen

Author

D. R. Gill, Michael E. Hayden, Marcelo Baquero-Ruiz, Andrea Gutierrez, Petteri Pusa, P. J. Nolan, Yasunori Yamazaki, K. Olchanski, Robert Thompson, M. J. Jenkins, M. D. Ashkezari, Leonid Kurchaninov, William Bertsche, Richard Hydomako, M. Charlton, P. D. Bowe, Eoin Butler, A. J. Humphries, Jonathan Wurtele, J. S. Hangst, L. V. Jørgensen, S. Seif El Nasr, Joel Fajans, A. Deller, S. L. Kemp, Svante Jonsell, A. Povilus, A. Olin, D. P. van der Werf, Francis Robicheaux, James William Storey, C. Ø. Rasmussen, Niels Madsen, D. M. Silveira, Stefan Eriksson, Walter Hardy, C. L. Cesar, Gorm Bruun Andresen, T. Friesen, Scott Chapman, M. C. Fujiwara, S. Menary, Chukman So, and E. Sarid

Subjects

Condensed Matter::Quantum Gases, Physics, Nuclear and High Energy Physics, Electronvolt, Plasma, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Antiproton, Magnetic trap, Antimatter, Atom, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Ground state, Antihydrogen

Abstract

Precision spectroscopic comparison of hydrogen and antihydrogen holds the promise of a sensitive test of the Charge-Parity-Time theorem and matter-antimatter equivalence. The clearest path towards realising this goal is to hold a sample of antihydrogen in an atomic trap for interrogation by electromagnetic radiation. Achieving this poses a huge experimental challenge, as state-of-the-art magnetic-minimum atom traps have well depths of only ∼1 T (∼0.5 K for ground state antihydrogen atoms). The atoms annihilate on contact with matter and must be ‘born’ inside the magnetic trap with low kinetic energies. At the ALPHA experiment, antihydrogen atoms are produced from antiprotons and positrons stored in the form of non-neutral plasmas, where the typical electrostatic potential energy per particle is on the order of electronvolts, more than 104 times the maximum trappable kinetic energy. In November 2010, ALPHA published the observation of 38 antiproton annihilations due to antihydrogen atoms that had been trapped for at least 172 ms and then released—the first instance of a purely antimatter atomic system confined for any length of time (Andresen et al., Nature 468:673, 2010). We present a description of the main components of the ALPHA traps and detectors that were key to realising this result. We discuss how the antihydrogen atoms were identified and how they were discriminated from the background processes. Since the results published in Andresen et al. (Nature 468:673, 2010), refinements in the antihydrogen production technique have allowed many more antihydrogen atoms to be trapped, and held for much longer times. We have identified antihydrogen atoms that have been trapped for at least 1,000 s in the apparatus (Andresen et al., Nature Physics 7:558, 2011). This is more than sufficient time to interrogate the atoms spectroscopically, as well as to ensure that they have relaxed to their ground state.

Published

2011

5. Antihydrogen formation by autoresonant excitation of antiproton plasmas

Author

T. Friesen, Marcelo Baquero-Ruiz, Andrea Gutierrez, P. J. Nolan, Michael E. Hayden, Robert Thompson, A. Povilus, J. S. Hangst, K. Olchanski, Francis Robicheaux, M. D. Ashkezari, Leonid Kurchaninov, P. T. Carpenter, J. L. Hurt, D. P. van der Werf, Niels Madsen, M. Charlton, Richard Hydomako, D. R. Gill, S. Menary, Jonathan Wurtele, P. D. Bowe, James William Storey, Chukman So, D. M. Silveira, Steve Chapman, William Bertsche, E. Sarid, Stefan Eriksson, Ryugo S. Hayano, A. Olin, Eoin Butler, Walter Hardy, A. J. Humphries, Svante Jonsell, Yasunori Yamazaki, Petteri Pusa, Joel Fajans, M. C. Fujiwara, C. L. Cesar, and Gorm Bruun Andresen

Subjects

Physics, Nuclear and High Energy Physics, Plasma, Condensed Matter Physics, Kinetic energy, Space charge, Atomic and Molecular Physics, and Optics, Charged particle, Nuclear physics, Physics::Plasma Physics, Antiproton, Excited state, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Antihydrogen, Excitation

Abstract

In efforts to trap antihydrogen, a key problem is the vast disparity between the neutral trap energy scale (\(\sim\!50\,\upmu\mathrm{eV}\)), and the energy scales associated with plasma confinement and space charge (~1 eV). In order to merge charged particle species for direct recombination, the larger energy scale must be overcome in a manner that minimizes the initial antihydrogen kinetic energy. This issue motivated the development of a novel injection technique utilizing the inherent nonlinear nature of particle oscillations in our traps. We demonstrated controllable excitation of the center-of-mass longitudinal motion of a thermal antiproton plasma using a swept-frequency autoresonant drive. When the plasma is cold, dense and highly collective in nature, we observe that the entire system behaves as a single-particle nonlinear oscillator, as predicted by a recent theory. In contrast, only a fraction of the antiprotons in a warm or tenuous plasma can be similarly excited. Antihydrogen was produced and trapped by using this technique to drive antiprotons into a positron plasma, thereby initiating atomic recombination. The nature of this injection overcomes some of the difficulties associated with matching the energies of the charged species used to produce antihydrogen.

Published

2011

6. Towards antihydrogen trapping and spectroscopy at ALPHA

Author

R. Lambo, Dean Wilding, Niels Madsen, M. D. Ashkezari, Ruyugo S. Hayano, A. J. Humphries, J. S. Hangst, Leonid Kurchaninov, William Bertsche, K. Olchanski, Yasunori Yamazaki, Svante Jonsell, M. Charlton, Walter Hardy, Jonathan Wurtele, Michael E. Hayden, Marcelo Baquero-Ruiz, S. Menary, M. C. Fujiwara, C. C. Bray, Eoin Butler, A. Povilus, Joel Fajans, Chukman So, Richard Hydomako, E. Sarid, T. Friesen, Dirk Peter van der Werf, C. L. Cesar, Gorm Bruun Andresen, Petteri Pusa, Francis Robicheaux, James William Storey, A. Olin, P. J. Nolan, D. R. Gill, P. D. Bowe, Steven Chapman, D. M. Silveira, and Robert Thompson

Subjects

Physics::General Physics, Nuclear and High Energy Physics, Atomic Physics (physics.atom-ph), CPT symmetry, Other Fields of Physics, Measure (physics), FOS: Physical sciences, 7. Clean energy, 01 natural sciences, Physics - Atomic Physics, High Energy Physics - Experiment, 010305 fluids & plasmas, Nuclear physics, High Energy Physics - Experiment (hep-ex), 0103 physical sciences, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, 010306 general physics, Spectroscopy, Antihydrogen, Condensed Matter::Quantum Gases, Physics, Annihilation, Large Hadron Collider, Condensed Matter Physics, Physics - Plasma Physics, Atomic and Molecular Physics, and Optics, Plasma Physics (physics.plasm-ph), Antiproton Decelerator, Antiproton, High Energy Physics::Experiment, Atomic physics

Abstract

Spectroscopy of antihydrogen has the potential to yield high-precision tests of the CPT theorem and shed light on the matter-antimatter imbalance in the Universe. The ALPHA antihydrogen trap at CERN's Antiproton Decelerator aims to prepare a sample of antihydrogen atoms confined in an octupole-based Ioffe trap and to measure the frequency of several atomic transitions. We describe our techniques to directly measure the antiproton temperature and a new technique to cool them to below 10 K. We also show how our unique position-sensitive annihilation detector provides us with a highly sensitive method of identifying antiproton annihilations and effectively rejecting the cosmic-ray background., 10 pages, 5 figures

Published

2011

7. Antihydrogen formation dynamics in a multipolar neutral anti-atom trap

Author

Robert Thompson, A. Olin, Richard Hydomako, S. Seif El Nasr, L. V. Jørgensen, Ryugo S. Hayano, James William Storey, C. L. Cesar, Gorm Bruun Andresen, J. S. Hangst, Francis Robicheaux, Walter Hardy, M. C. Fujiwara, C. C. Bray, William Bertsche, Yasunori Yamazaki, Leonid Kurchaninov, P. J. Nolan, K. Olchanski, D. P. van der Werf, A. J. Humphries, R. Lambo, Joel Fajans, Jonathan Wurtele, E. Butler, Niels Madsen, P. D. Bowe, M. Charlton, S. J. Kerrigan, D. M. Silveira, S. Chapman, Petteri Pusa, D. R. Gill, A. Povilus, E. Sarid, and Michael E. Hayden

Subjects

Physics::General Physics, Nuclear and High Energy Physics, Atomic Physics (physics.atom-ph), Binding energy, FOS: Physical sciences, Trapping, 01 natural sciences, 010305 fluids & plasmas, High Energy Physics - Experiment, Physics - Atomic Physics, High Energy Physics - Experiment (hep-ex), 0103 physical sciences, Atom, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, 010306 general physics, Antihydrogen, Physics, Annihilation, Energetic neutral atom, Particle transport, Physics - Plasma Physics, Non-neutral plasma, Magnetic field, Plasma Physics (physics.plasm-ph), Antiproton, CPT, Atomic physics, Particle Physics - Experiment

Abstract

Antihydrogen production in a neutral atom trap formed by an octupole-based magnetic field minimum is demonstrated using field-ionization of weakly bound anti-atoms. Using our unique annihilation imaging detector, we correlate antihydrogen detection by imaging and by field-ionization for the first time. We further establish how field-ionization causes radial redistribution of the antiprotons during antihydrogen formation and use this effect for the first simultaneous measurements of strongly and weakly bound antihydrogen atoms. Distinguishing between these provides critical information needed in the process of optimizing for trappable antihydrogen. These observations are of crucial importance to the ultimate goal of performing CPT tests involving antihydrogen, which likely depends upon trapping the anti-atom. Antihydrogen production in a neutral atom trap formed by an octupole-based magnetic field minimum is demonstrated using field-ionization of weakly bound anti-atoms. Using our unique annihilation imaging detector, we correlate antihydrogen detection by imaging and by field-ionization for the first time. We further establish how field-ionization causes radial redistribution of the antiprotons during antihydrogen formation and use this effect for the first simultaneous measurements of strongly and weakly bound antihydrogen atoms. Distinguishing between these provides critical information needed in the process of optimizing for trappable antihydrogen. These observations are of crucial importance to the ultimate goal of performing CPT tests involving antihydrogen, which likely depends upon trapping the anti-atom.

Published

2010

8. A magnetic trap for antihydrogen confinement

Author

M. J. Jenkins, A. Deutsch, Yasunori Yamazaki, L. G. C. Posada, A. J. Boston, Robert Page, Marielle Chartier, E. Sarid, A.K. Ghosh, P. J. Nolan, Joel Fajans, K. Gomberoff, Brett Parker, L. V. Jørgensen, William Bertsche, A. Povilus, P. Ko, J. Escallier, P. D. Bowe, Ryugo S. Hayano, D. M. Silveira, M. Charlton, Niels Madsen, J. S. Hangst, D. P. van der Werf, Scott Chapman, M. C. Fujiwara, R. Funakoshi, and C. L. Cesar

Subjects

Physics, Nuclear and High Energy Physics, Large Hadron Collider, Hydrogen, chemistry.chemical_element, Penning trap, Nuclear physics, Trap (computing), chemistry, Antiproton, Magnetic trap, Atomic physics, Ground state, Antihydrogen, Instrumentation

Abstract

The goal of the ALPHA collaboration at CERN is to test CPT conservation by comparing the 1S–2S transitions of hydrogen and antihydrogen. To reach the ultimate accuracy of 1 part in 10 18 , the (anti)atoms must be trapped. Using current technology, only magnetic minimum traps can confine (anti)hydrogen. In this paper, the design of the ALPHA antihydrogen trap and the results of measurements on a prototype system will be presented. The trap depth of the final system will be 1.16 T, corresponding to a temperature of 0.78 K for ground state antihydrogen.

Published

2006

9. Using stochastic acceleration to place experimental limits on the charge of antihydrogen

Author

Jonathan Wurtele, Francis Robicheaux, A. E. Charman, Marcelo Baquero-Ruiz, A. Povilus, Joel Fajans, Andrey Zhmoginov, and A. Little

Subjects

Physics::General Physics, Hydrogen, Atomic Physics (physics.atom-ph), CPT symmetry, Fluids & Plasmas, Other Fields of Physics, FOS: Physical sciences, General Physics and Astronomy, chemistry.chemical_element, charge anomaly, 01 natural sciences, Measure (mathematics), physics.atom-ph, Physics - Atomic Physics, Acceleration, Electric field, 0103 physical sciences, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, 010306 general physics, Antihydrogen, Physics, antihydrogen, 010308 nuclear & particles physics, Charge (physics), chemistry, Physical Sciences, CPT, Atomic physics

Abstract

Assuming hydrogen is charge neutral, CPT invariance demands that antihydrogen also be charge neutral. Quantum anomaly cancellation also demands that antihydrogen be charge neutral. Standard techniques based on measurements of macroscopic quantities of atoms cannot be used to measure the charge of antihydrogen. In this paper, we describe how the application of randomly oscillating electric fields to a sample of trapped antihydrogen atoms, a form of stochastic acceleration, can be used to place experimental limits on this charge. Assuming hydrogen is charge neutral, CPT invariance demands that antihydrogen also be charge neutral. Quantum anomaly cancellation also demands that antihydrogen be charge neutral. Standard techniques based on measurements of macroscopic quantities of atoms cannot be used to measure the charge of antihydrogen. In this paper, we describe how the application of randomly oscillating electric fields to a sample of trapped antihydrogen atoms, a form of stochastic acceleration, can be used to place experimental limits on this charge. Assuming hydrogen is charge neutral, CPT invariance demands that antihydrogen also be charge neutral. Quantum anomaly cancellation also demands that antihydrogen be charge neutral. Standard techniques based on measurements of macroscopic quantities of atoms cannot be used to measure the charge of antihydrogen. In this paper, we describe how the application of randomly oscillating electric fields to a sample of trapped antihydrogen atoms, a form of stochastic acceleration, can be used to place experimental limits on this charge.

Published

2014

10. Evaporative cooling of antiprotons for the production of trappable antihydrogen

Author

K. Olchanski, Robert Thompson, Michael E. Hayden, J. S. Hangst, D. R. Gill, M. D. Ashkezari, Leonid Kurchaninov, William Bertsche, D. P. van der Werf, D. M. Silveira, A. Olin, Svante Jonsell, Marcelo Baquero-Ruiz, Walter Hardy, M. Charlton, Niels Madsen, Jonathan Wurtele, Petteri Pusa, Richard Hydomako, Francis Robicheaux, P. D. Bowe, Joel Fajans, Eoin Butler, A. Povilus, C. L. Cesar, Gorm Bruun Andresen, P. J. Nolan, John W. V. Storey, M. C. Fujiwara, T. Friesen, Scott Chapman, E. Sarid, S. Menary, and Chukman So

Subjects

Nuclear physics, Physics, Particle number, Antiproton, Evaporation, Trapping, Plasma, Physics::Atomic Physics, Atomic physics, Antihydrogen, Charged particle, Evaporative cooler

Abstract

We describe the implementation of evaporative cooling of charged particles in the ALPHA apparatus. Forced evaporation has been applied to cold samples of antiprotons held in Malmberg-Penning traps. Temperatures on the order of 10 K were obtained, while retaining a significant fraction of the initial number of particles. We have developed a model for the evaporation process based on simple rate equations and applied it succesfully to the experimental data. We have also observed radial re-distribution of the clouds following evaporation, explained by simple conservation laws. We discuss the relevance of this technique for the recent demonstration of magnetic trapping of antihydrogen.

Published

2013

11. Microwave-plasma interactions studied via mode diagnostics in ALPHA

Author

John W. V. Storey, P. D. Bowe, M. E. Hayden, Yasunori Yamazaki, D. P. van der Werf, Jonathan Wurtele, William Bertsche, A. Olin, Robert Thompson, Joel Fajans, C. L. Cesar, Niels Madsen, K. Olchanski, E. Sarid, Stefan Eriksson, Gorm Bruun Andresen, Petteri Pusa, Ryugo S. Hayano, M. D. Ashkezari, T. Friesen, Leonid Kurchaninov, M. C. Fujiwara, Richard Hydomako, Marcelo Baquero-Ruiz, Andrea Gutierrez, M. Charlton, Francis Robicheaux, A. J. Humphries, A. Povilus, Svante Jonsell, S. Menary, Eoin Butler, Chukman So, Steve Chapman, J. S. Hangst, W. N. Hardy, P. J. Nolan, D. R. Gill, and D. M. Silveira

Subjects

Physics, Nuclear and High Energy Physics, Cyclotron resonance, Plasma, Condensed Matter Physics, Penning trap, Non-neutral plasmas, Atomic and Molecular Physics, and Optics, Ion source, Physics::Plasma Physics, Physics::Space Physics, Plasma diagnostics, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Spectroscopy, Antihydrogen

Abstract

The goal of the ALPHA experiment is the production, trapping and spectroscopy of antihydrogen. A direct comparison of the ground state hyperfine spectra in hydrogen and antihydrogen has the potential to be a high-precision test of CPT symmetry. We present a novel method for measuring the strength of a microwave field for hyperfine spectroscopy in a Penning trap. This method incorporates a non-destructive plasma diagnostic system based on electrostatic modes within an electron plasma. We also show how this technique can be used to measure the cyclotron resonance of the electron plasma, which can potentially serve as a non-destructive measurement of plasma temperature.

Published

2012

12. Centrifugal Separation and Equilibration Dynamics in an Electron-Antiproton Plasma

Author

William Bertsche, M. D. Ashkezari, A. J. Humphries, S. Menary, Robert Thompson, M. Charlton, Chukman So, Svante Jonsell, Eoin Butler, D. R. Gill, D. P. van der Werf, D. M. Silveira, Niels Madsen, Yasunori Yamazaki, Petteri Pusa, Walter Hardy, E. Sarid, Jonathan Wurtele, Marcelo Baquero-Ruiz, Andrea Gutierrez, Michael E. Hayden, P. D. Bowe, Joel Fajans, A. Olin, Richard Hydomako, J. S. Hangst, A. Povilus, P. J. Nolan, James William Storey, Francis Robicheaux, A. Deller, Stefan Eriksson, T. Friesen, Scott Chapman, C. L. Cesar, Gorm Bruun Andresen, and M. C. Fujiwara

Subjects

Physics, Antiparticle, Range (particle radiation), Atomic Physics (physics.atom-ph), Other Fields of Physics, FOS: Physical sciences, General Physics and Astronomy, Electron, Plasma, 01 natural sciences, Physics - Plasma Physics, High Energy Physics - Experiment, Physics - Atomic Physics, 010305 fluids & plasmas, Plasma Physics (physics.plasm-ph), High Energy Physics - Experiment (hep-ex), Physics::Plasma Physics, Antiproton, Antimatter, 0103 physical sciences, Physics::Atomic Physics, Atomic physics, 010306 general physics, Nucleon, Antihydrogen

Abstract

Charges in cold, multiple-species, non-neutral plasmas separate radially by mass, forming centrifugally-separated states. Here, we report the first detailed measurements of such states in an electron-antiproton plasma, and the first observations of the separation dynamics in any centrifugally-separated system. While the observed equilibrium states are expected and in agreement with theory, the equilibration time is approximately constant over a wide range of parameters, a surprising and as yet unexplained result. Electron-antiproton plasmas play a crucial role in antihydrogen trapping experiments. Charges in cold, multiple-species, non-neutral plasmas separate radially by mass, forming centrifugally-separated states. Here, we report the first detailed measurements of such states in an electron-antiproton plasma, and the first observations of the separation dynamics in any centrifugally-separated system. While the observed equilibrium states are expected and in agreement with theory, the equilibration time is approximately constant over a wide range of parameters, a surprising and as yet unexplained result. Electron-antiproton plasmas play a crucial role in antihydrogen trapping experiments.

Published

2011

13. Search for trapped antihydrogen

Author

R. Lambo, C. L. Cesar, Gorm Bruun Andresen, Niels Madsen, A. J. Humphries, T. Friesen, Scott Chapman, Svante Jonsell, James William Storey, Robert Thompson, A. Povilus, Marcelo Baquero-Ruiz, M. C. Fujiwara, C. C. Bray, Richard Hydomako, Jonathan Wurtele, Michael E. Hayden, S. Menary, L. V. Jørgensen, D. Wilding, Petteri Pusa, Chukman So, S. Seif El Nasr, Walter Hardy, K. Olchanski, A. Olin, J. S. Hangst, D. P. van der Werf, Ryugo S. Hayano, M. D. Ashkezari, Leonid Kurchaninov, Yasunori Yamazaki, E. Sarid, M. Charlton, Joel Fajans, Francis Robicheaux, E. Butler, William Bertsche, P. D. Bowe, D. M. Silveira, P. J. Nolan, and D. R. Gill

Subjects

Antimatter, Nuclear and High Energy Physics, Atomic Physics (physics.atom-ph), FOS: Physical sciences, Cosmic ray, 01 natural sciences, Physics - Atomic Physics, High Energy Physics - Experiment, 010305 fluids & plasmas, Nuclear physics, High Energy Physics - Experiment (hep-ex), Positron, 0103 physical sciences, Nuclear Physics - Experiment, Physics::Atomic Physics, Detectors and Experimental Techniques, 010306 general physics, Antihydrogen, Physics, Condensed Matter::Quantum Gases, Annihilation, Plasma, Antiproton Decelerator, Antiproton, Atom trap, CPT, Atomic physics

Abstract

We present the results of an experiment to search for trapped antihydrogen atoms with the ALPHA antihydrogen trap at the CERN Antiproton Decelerator. Sensitive diagnostics of the temperatures, sizes, and densities of the trapped antiproton and positron plasmas have been developed, which in turn permitted development of techniques to precisely and reproducibly control the initial experimental parameters. The use of a position-sensitive annihilation vertex detector, together with the capability of controllably quenching the superconducting magnetic minimum trap, enabled us to carry out a high-sensitivity and low-background search for trapped synthesised antihydrogen atoms. We aim to identify the annihilations of antihydrogen atoms held for at least 130 ms in the trap before being released over ~30 ms. After a three-week experimental run in 2009 involving mixing of 10^7 antiprotons with 1.3 10^9 positrons to produce 6 10^5 antihydrogen atoms, we have identified six antiproton annihilation events that are consistent with the release of trapped antihydrogen. The cosmic ray background, estimated to contribute 0.14 counts, is incompatible with this observation at a significance of 5.6 sigma. Extensive simulations predict that an alternative source of annihilations, the escape of mirror-trapped antiprotons, is highly unlikely, though this possibility has not yet been ruled out experimentally., Comment: 12 pages, 7 figures

Published

2011

14. Autoresonant Excitation of Antiproton Plasmas

Author

P. D. Bowe, J. L. Hurt, P. J. Nolan, A. Olin, K. Olchanski, Yasunori Yamazaki, Jonathan Wurtele, M. D. Ashkezari, T. Friesen, J. S. Hangst, William Bertsche, D. M. Silveira, Francis Robicheaux, D. R. Gill, Richard Hydomako, Scott Chapman, D. P. van der Werf, M. Charlton, Joel Fajans, C. L. Cesar, Niels Madsen, P. T. Carpenter, Walter Hardy, Gorm Bruun Andresen, Michael E. Hayden, Marcelo Baquero-Ruiz, M. C. Fujiwara, Eoin Butler, James William Storey, Petteri Pusa, Robert Thompson, A. J. Humphries, Svante Jonsell, A. Povilus, E. Sarid, S. Menary, and Chukman So

Subjects

Physics, Antiparticle, General Physics and Astronomy, Plasma, Positron, Physics::Plasma Physics, Antiproton, Excited state, Antimatter, Physics::Accelerator Physics, Physics::Atomic Physics, Atomic physics, Antihydrogen, Excitation

Abstract

We demonstrate controllable excitation of the center-of-mass longitudinal motion of a thermal antiproton plasma using a swept-frequency autoresonant drive. When the plasma is cold, dense, and highly collective in nature, we observe that the entire system behaves as a single-particle nonlinear oscillator, as predicted by a recent theory. In contrast, only a fraction of the antiprotons in a warm plasma can be similarly excited. Antihydrogen was produced and trapped by using this technique to drive antiprotons into a positron plasma, thereby initiating atomic recombination.

Published

2011

15. Antimatter transport processes

Author

R. Lambo, M. C. Fujiwara, Robert Thompson, D R Gill, K. Olchanski, A. J. Humphries, Richard Hydomako, William Bertsche, Yasunori Yamazaki, James William Storey, M. D. Ashkezari, Marcelo Baquero-Ruiz, Svante Jonsell, L. V. Jørgensen, Leonid Kurchaninov, Joel Fajans, Jonathan Wurtele, D. P. van der Werf, A. Olin, T. Friesen, M. Charlton, Walter Hardy, A. Povilus, C. L. Cesar, Michael E. Hayden, Scott Chapman, Niels Madsen, Gorm Bruun Andresen, P Pusa, Ryugo S. Hayano, E. Sarid, P. J. Nolan, C. C. Bray, S. Menary, Chukman So, J. S. Hangst, P. D. Bowe, E. Butler, D. M. Silveira, and Francis Robicheaux

Subjects

Condensed Matter::Quantum Gases, Physics, History, Antiparticle, Energetic neutral atom, Plasma, Computer Science Applications, Education, Nuclear physics, Antiproton Decelerator, Antiproton, Antimatter, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Atomic physics, Antihydrogen, Lepton

Abstract

A comparison of the 1S-2S transitions of hydrogen and antihydrogen will yield a stringent test of CPT conservation. Necessarily, the antihydrogen atoms need to be trapped to perform high precision spectroscopy measurements. Therefore, an approximately 0.75 T deep neutral atom trap, equivalent to about 0.5 K for ground state (anti)hydrogen atoms, has been superimposed on a Penning-Malmberg trap in which the anti-atoms are formed. The antihydrogen atoms are produced following a number of steps. A bunch of antiprotons from the CERN Antiproton Decelerator is caught in a Penning-Malmberg trap and subsequently sympathetically cooled and then compressed using rotating wall electric fields. A positron plasma, formed in a separate accumulator, is transported to the main system and also compressed. Antihydrogen atoms are then formed by mixing the antiprotons and positrons. The velocity of the anti-atoms, and their binding energies, will strongly depend on the initial conditions of the constituent particles, for example their temperatures and densities, and on the details of the mixing process. In this paper the complete lifecycle of antihydrogen atoms will be presented, starting with the production of the constituent antiparticles and the description of the manipulations necessary to prepare them appropriately for antihydrogen formation. The latter will also be described, as will the possible fates of the anti-atoms.

Published

2010

16. Antiproton, positron, and electron imaging with a microchannel plate/phosphor detector

Author

G. B. Andresen, W. Bertsche, P. D. Bowe, C. C. Bray, E. Butler, C. L. Cesar, S. Chapman, M. Charlton, S. Seif El Nasr, J. Fajans, M. C. Fujiwara, D. R. Gill, J. S. Hangst, W. N. Hardy, R. S. Hayano, M. E. Hayden, A. J. Humphries, R. Hydomako, L. V. Jørgensen, S. J. Kerrigan, L. Kurchaninov, R. Lambo, N. Madsen, P. Nolan, K. Olchanski, A. Olin, A. P. Povilus, P. Pusa, E. Sarid, D. M. Silveira, J. W. Storey, R. I. Thompson, D. P. van der Werf, Y. Yamazaki, and null ALPHA Collaboration

Subjects

Physics, Detector, Phosphor, Electron, Trapping, Positron, Antiproton, Physics::Accelerator Physics, High Energy Physics::Experiment, Microchannel plate detector, Physics::Atomic Physics, Atomic physics, Antihydrogen, Instrumentation

Abstract

A microchannel plate (MCP)/phosphor screen assembly has been used to destructively measure the radial profile of cold, confined antiprotons, electrons, and positrons in the ALPHA experiment, with the goal of using these trapped particles for antihydrogen creation and confinement. The response of the MCP to low energy (10-200 eV

Published

2009

17. A novel antiproton radial diagnostic based on octupole induced ballistic loss

Author

Yasunori Yamazaki, Robert Page, William Bertsche, K. Olchanski, Joel Fajans, Jonathan Wurtele, D. M. Silveira, James William Storey, D. P. van der Werf, C. C. Bray, R. Funakoshi, D. R. Gill, Francis Robicheaux, S. Chapman, M. E. Hayden, Richard Hydomako, Leonid Kurchaninov, J. S. Hangst, Eoin Butler, W. N. Hardy, R. Lambo, Niels Madsen, P. J. Nolan, M. Charlton, C. L. Cesar, Gorm Bruun Andresen, L. V. Jørgensen, Petteri Pusa, M. J. Jenkins, E. Sarid, A. J. Humphries, Makoto Fujiwara, P. D. Bowe, A. Olin, Ryugo S. Hayano, A. Povilus, Robert Thompson, and S. Seif El Nasr

Subjects

Physics, Field (physics), Atomic Physics (physics.atom-ph), FOS: Physical sciences, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Physics - Atomic Physics, Nuclear physics, Antiproton, 0103 physical sciences, Physics::Accelerator Physics, Physics::Atomic Physics, Atomic physics, Detectors and Experimental Techniques, Nuclear Experiment (nucl-ex), 010306 general physics, Antihydrogen, Nuclear Experiment

Abstract

We report results from a novel diagnostic that probes the outer radial profile of trapped antiproton clouds. The diagnostic allows us to determine the profile by monitoring the time-history of antiproton losses that occur as an octupole field in the antiproton confinement region is increased. We show several examples of how this diagnostic helps us to understand the radial dynamics of antiprotons in normal and nested Penning-Malmberg traps. Better understanding of these dynamics may aid current attempts to trap antihydrogen atoms. We report results from a novel diagnostic that probes the outer radial profile of trapped antiproton clouds. The diagnostic allows us to determine the profile by monitoring the time-history of antiproton losses that occur as an octupole field in the antiproton confinement region is increased. We show several examples of how this diagnostic helps us to understand the radial dynamics of antiprotons in normal and nested Penning-Malmberg traps. Better understanding of these dynamics may aid current attempts to trap antihydrogen atoms.

Published

2008

18. Compression of Antiproton Clouds for Antihydrogen Trapping

Author

Leonid Kurchaninov, Francis Robicheaux, Jonathan Wurtele, Niels Madsen, M. Charlton, A. Povilus, S. Chapman, K. Olchanski, William Bertsche, S. Seif El Nasr, R. Lambo, C. L. Cesar, Gorm Bruun Andresen, D. R. Gill, M. E. Hayden, D. M. Silveira, Yasunori Yamazaki, M. C. Fujiwara, M. J. Jenkins, C. C. Bray, R. Funakoshi, D. P. van der Werf, Joel Fajans, J. S. Hangst, Robert Thompson, P. D. Bowe, W. N. Hardy, P. J. Nolan, A. Olin, Richard Hydomako, L. V. Jørgensen, Ryugo S. Hayano, James William Storey, E. Sarid, Eoin Butler, and Petteri Pusa

Subjects

Hydrogen, General Physics and Astronomy, chemistry.chemical_element, FOS: Physical sciences, Electron, Trapping, 01 natural sciences, complex mixtures, 010305 fluids & plasmas, Nuclear physics, Physics::Plasma Physics, 0103 physical sciences, Area density, Physics::Atomic Physics, Nuclear Experiment (nucl-ex), 010306 general physics, Antihydrogen, Nuclear Experiment, Nuclear Physics, Physics, Plasma, Compression (physics), chemistry, Antiproton, sense organs, Atomic physics

Abstract

Control of the radial profile of trapped antiproton clouds is critical to trapping antihydrogen. We report the first detailed measurements of the radial manipulation of antiproton clouds, including areal density compressions by factors as large as ten, by manipulating spatially overlapped electron plasmas. We show detailed measurements of the near-axis antiproton radial profile and its relation to that of the electron plasma. Control of the radial profile of trapped antiproton clouds is critical to trapping antihydrogen. We report the first detailed measurements of the radial manipulation of antiproton clouds, including areal density compressions by factors as large as ten, by manipulating spatially overlapped electron plasmas. We show detailed measurements of the near-axis antiproton radial profile and its relation to that of the electron plasma.

Published

2008

19. Trapping and evolution dynamics of ultracold two-component plasmas

Author

B. Knuffman, Jaehyuk Choi, A. P. Povilus, Xuhuai Zhang, and Georg Raithel

Subjects

Condensed Matter::Quantum Gases, Physics, Trap (computing), Oscillation, General Physics and Astronomy, Physics::Atomic Physics, Trapping, Plasma, Electron, Ion trap, Atomic physics, Penning trap, Ion

Abstract

We demonstrate the trapping of a strongly magnetized, quasineutral ultracold plasma in a nested Penning trap with a background field of 2.9 T. Electrons remain trapped in this system for several milliseconds. Early in the evolution, the dynamics are driven by a breathing-mode oscillation in the ionic charge distribution, which modulates the electron trap depth. Over longer times scales, the electronic component undergoes cooling. Trap loss resulting from E x B drift is characterized.

Published

2007

20. Antimatter Plasmas in a Multipole Trap for Antihydrogen

Author

D. R. Gill, Niels Madsen, J. S. Hangst, Francis Robicheaux, Helmut H. Telle, A. Olin, A. Povilus, C. L. Cesar, Marielle Chartier, K. Olchanski, Jonathan Wurtele, E. Sarid, D. P. van der Werf, P. J. Nolan, Gorm Bruun Andresen, Leonid Kurchaninov, Robert Thompson, William Bertsche, K. Gomberoff, M. Charlton, Richard Hydomako, P. D. Bowe, Yasunori Yamazaki, James William Storey, Scott Chapman, M. J. Jenkins, L. V. Jørgensen, Ryugo S. Hayano, Joel Fajans, M. C. Fujiwara, R. Funakoshi, D. M. Silveira, A. Deutsch, and A. J. Boston

Subjects

Condensed Matter::Quantum Gases, Physics, General Physics and Astronomy, Plasma, Penning trap, Nuclear physics, Trap (computing), Antiproton, Magnetic trap, Antimatter, Physics::Atomic and Molecular Clusters, Physics::Accelerator Physics, Physics::Atomic Physics, Ion trap, Atomic physics, Antihydrogen

Abstract

We have demonstrated storage of plasmas of the charged constituents of the antihydrogen atom, antiprotons and positrons, in a Penning trap surrounded by a minimum-B magnetic trap designed for holding neutral antiatoms. The neutral trap comprises a superconducting octupole and two superconducting, solenoidal mirror coils. We have measured the storage lifetimes of antiproton and positron plasmas in the combined Penning-neutral trap, and compared these to lifetimes without the neutral trap fields. The magnetic well depth was 0.6 T, deep enough to trap ground state antihydrogen atoms of up to about 0.4 K in temperature. We have demonstrated that both particle species can be stored for times long enough to permit antihydrogen production and trapping studies.

Published

2007

21. Landau Quantization and Time Dependence in the Ionization of Cold, Strongly Magnetized Rydberg Atoms

Author

Eberhard Sebastian Hansis, Jaehyuk Choi, Georg Raithel, Jeffrey R. Guest, and A. P. Povilus

Subjects

Physics, General Physics and Astronomy, Landau quantization, symbols.namesake, Rydberg constant, Autoionization, Metastability, Ionization, Rydberg atom, Physics::Atomic and Molecular Clusters, symbols, Rydberg formula, Rydberg matter, Physics::Atomic Physics, Atomic physics

Abstract

The electric-field-ionization and autoionization behavior of cold Rydberg atoms of $^{85}\mathrm{Rb}$ in magnetic fields up to 6 T is investigated. Multiple ionization potentials and field-ionization bands reflecting the Landau energy quantization of the quasifree Rydberg electron are observed. The time-resolved and state-selective field-ionization study provides evidence of $m$ mixing and spin flips of the Rydberg electron. Spin-orbit coupling combined with $m$ mixing gives rise to a Feshbach-type autoionization of metastable positive-energy atoms.

Published

2005

22. Magnetic Trapping of Long-Lived Cold Rydberg Atoms

Author

Georg Raithel, Jaehyuk Choi, Eberhard Sebastian Hansis, Jeffrey R. Guest, and A. P. Povilus

Subjects

Condensed Matter::Quantum Gases, Physics, Magnetic moment, General Physics and Astronomy, Quantum Physics, symbols.namesake, Ultracold atom, Excited state, Magnetic trap, Rydberg atom, Physics::Atomic and Molecular Clusters, Rydberg formula, symbols, Rydberg matter, Physics::Atomic Physics, Atomic physics, Antihydrogen

Abstract

We report on the trapping of long-lived strongly magnetized Rydberg atoms. {sup 85}Rb atoms are laser cooled and collected in a superconducting magnetic trap with a strong bias field (2.9 T) and laser excited to Rydberg states. Collisions scatter a small fraction of the Rydberg atoms into long-lived high-angular momentum 'guiding-center' Rydberg states, which are magnetically trapped. The Rydberg atomic cloud is examined using a time-delayed, position-sensitive probe. We observe magnetic trapping of these Rydberg atoms for times up to 200 ms. Oscillations of the Rydberg-atom cloud in the trap reveal an average magnetic moment of the trapped Rydberg atoms of {approx_equal}-8{mu}{sub B}. These results provide guidance for other Rydberg-atom trapping schemes and illuminate a possible route for trapping antihydrogen.

Published

2005

23. Laser cooling and magnetic trapping at several tesla

Author

Eberhard Sebastian Hansis, Georg Raithel, Jeffrey R. Guest, A. P. Povilus, and Jaehyuk Choi

Subjects

Condensed Matter::Quantum Gases, Superconductivity, Materials science, General Physics and Astronomy, Photoionization, Plasma, Laser, Magnetic field, law.invention, law, Ultracold atom, Optical molasses, Laser cooling, Physics::Atomic Physics, Atomic physics

Abstract

Laser cooling and magnetic trapping of (85)Rb atoms have been performed in extremely strong and tunable magnetic fields, extending these techniques to a new regime and setting the stage for a variety of cold atom and plasma experiments. Using a superconducting Ioffe-Pritchard trap and an optical molasses, 2.4 x 10(7) atoms were laser cooled to the Doppler limit and magnetically trapped at bias fields up to 2.9 T. At magnetic fields up to 6 T, 3 x 10(6) cold atoms were laser cooled in a pulsed loading scheme. These bias fields are well beyond an order of magnitude larger than those in previous experiments. Loading rates, molasses lifetimes, magnetic-trapping times, and temperatures were measured using photoionization and electron detection.

Published

2004

24. Autoresonant-spectrometric determination of the residual gas composition in the ALPHA experiment apparatus

Author

K. Olchanski, S. C. Napoli, D. M. Silveira, Robert Thompson, Eoin Butler, Niels Madsen, M. E. Hayden, Marcelo Baquero-Ruiz, Andrea Gutierrez, Jonathan Wurtele, S. Menary, A. Povilus, Steve Chapman, William Bertsche, Andrey Zhmoginov, Chukman So, P. J. Nolan, Petteri Pusa, J. S. Hangst, A. Capra, A. Little, S. Stracka, D. R. Gill, Francis Robicheaux, C. Ø. Rasmussen, W. N. Hardy, J. T. K. McKenna, A. Olin, D. P. van der Werf, Svante Jonsell, E. Sarid, Stefan Eriksson, M. C. Fujiwara, C. L. Cesar, C. Amole, M. D. Ashkezari, Leonid Kurchaninov, Joel Fajans, M. Charlton, Matthew Turner, T. Friesen, and C. A. Isaac

Subjects

Condensed Matter::Quantum Gases, Range (particle radiation), Materials science, Plasma, Residual, Ion, Trap (computing), Physics::Plasma Physics, Measuring instrument, Physics::Atomic Physics, Gas composition, Atomic physics, Antihydrogen, Instrumentation

Abstract

Knowledge of the residual gas composition in the ALPHA experiment apparatus is important in our studies of antihydrogen and nonneutral plasmas. A technique based on autoresonant ion extraction from an electrostatic potential well has been developed that enables the study of the vacuum in our trap. Computer simulations allow an interpretation of our measurements and provide the residual gas composition under operating conditions typical of those used in experiments to produce, trap, and study antihydrogen. The methods developed may also be applicable in a range of atomic and molecular trap experiments where Penning-Malmberg traps are used and where access is limited.

Published

2013

25. Discriminating between antihydrogen and mirror-trapped antiprotons in a minimum-B trap

Author

T. Friesen, K. Olchanski, Scott Chapman, Richard Hydomako, E. Sarid, A. Olin, A. Deller, Petteri Pusa, John W. V. Storey, Niels Madsen, Robert Thompson, Michael E. Hayden, D. M. Silveira, Eoin Butler, Marcelo Baquero-Ruiz, Andrea Gutierrez, M. C. Fujiwara, D. R. Gill, Jonathan Wurtele, A. J. Humphries, A. Povilus, Svante Jonsell, C. Amole, P. J. Nolan, Stefan Eriksson, S. Menary, Francis Robicheaux, D. P. van der Werf, Walter Hardy, C. L. Cesar, Chukman So, Gorm Bruun Andresen, W. Bertsche, Joel Fajans, J. S. Hangst, M. D. Ashkezari, Leonid Kurchaninov, and M. Charlton

Subjects

Condensed Matter::Quantum Gases, Physics, Physics::General Physics, Annihilation, Large Hadron Collider, General Physics and Astronomy, Trap (computing), Positron, Antiproton, Magnet, Electric field, Physics::Accelerator Physics, Physics::Atomic Physics, Atomic physics, Antihydrogen

Abstract

Recently, antihydrogen atoms were trapped at CERN in a magnetic minimum (minimum-B) trap formed by superconducting octupole and mirror magnet coils. The trapped antiatoms were detected by rapidly turning off these magnets, thereby eliminating the magnetic minimum and releasing any antiatoms contained in the trap. Once released, these antiatoms quickly hit the trap wall, whereupon the positrons and antiprotons in the antiatoms annihilated. The antiproton annihilations produce easily detected signals; we used these signals to prove that we trapped antihydrogen. However, our technique could be confounded by mirror-trapped antiprotons, which would produce seemingly-identical annihilation signals upon hitting the trap wall. In this paper, we discuss possible sources of mirror-trapped antiprotons and show that antihydrogen and antiprotons can be readily distinguished, often with the aid of applied electric fields, by analyzing the annihilation locations and times. We further discuss the general properties of antiproton and antihydrogen trajectories in this magnetic geometry, and reconstruct the antihydrogen energy distribution from the measured annihilation time history.

Published

2012

26. Magnetic multipole induced zero-rotation frequency bounce-resonant loss in a Penning–Malmberg trap used for antihydrogen trapping

Author

Leonid Kurchaninov, M. Charlton, E. Sarid, K. Olchanski, A. Olin, William Bertsche, Michael E. Hayden, Jonathan Wurtele, James William Storey, Robert Thompson, D. M. Silveira, Petteri Pusa, D. P. van der Werf, S. Seif El Nasr, A. J. Humphries, Niels Madsen, Eoin Butler, P. J. Nolan, Yasunori Yamazaki, Walter Hardy, Joel Fajans, A. Povilus, C. L. Cesar, Gorm Bruun Andresen, C. C. Bray, Francis Robicheaux, J. Keller, M. C. Fujiwara, D. R. Gill, R. Lambo, S. J. Kerrigan, Scott Chapman, Ryugo S. Hayano, Richard Hydomako, and L. V. Jørgensen

Subjects

Condensed Matter::Quantum Gases, Physics, Zero (complex analysis), Trapping, Condensed Matter Physics, Rotation, Trap (computing), Transverse plane, Physics::Plasma Physics, Antiproton, Physics::Atomic Physics, Atomic physics, Nuclear Experiment, Multipole expansion, Antihydrogen

Abstract

In many antihydrogen trapping schemes, antiprotons held in a short-well Penning–Malmberg trap are released into a longer well. This process necessarily causes the bounce-averaged rotation frequency Ω¯r of the antiprotons around the trap axis to pass through zero. In the presence of a transverse magnetic multipole, experiments and simulations show that many antiprotons (over 30% in some cases) can be lost to a hitherto unidentified bounce-resonant process when Ω¯r is close to zero.

Published

2009

27. The ALPHA antihydrogen trapping apparatus

Author

M. J. Jenkins, Ryugo S. Hayano, D. R. Gill, K. Olchanski, James William Storey, Yasunori Yamazaki, S. J. Kerrigan, Petteri Pusa, J. L. Hurt, D. P. van der Werf, Richard Hydomako, A. J. Humphries, Francis Robicheaux, Joel Fajans, Svante Jonsell, D. M. Silveira, D. Seddon, Niels Madsen, J. T. K. McKenna, Brett Parker, Marcelo Baquero-Ruiz, Andrea Gutierrez, E. Sarid, L. V. Jørgensen, S. Menary, Jonathan Wurtele, D. Wells, A. Deller, M. E. Hayden, Chukman So, A. Olin, M. D. Ashkezari, Leonid Kurchaninov, P. J. Nolan, M. Charlton, P. D. Bowe, Andrew Marone, Robert Thompson, A. Capra, C. Amole, Eoin Butler, J. Escallier, Stefan Eriksson, S. Seif El Nasr, P. T. Carpenter, William Bertsche, J. Thornhill, A. Povilus, T. Friesen, C. A. Isaac, Scott Chapman, C. L. Cesar, J. S. Hangst, Gorm Bruun Andresen, W. N. Hardy, and M. C. Fujiwara

Subjects

Nuclear and High Energy Physics, Antiparticle, Trapping, Antiprotons, Atomic, Nuclear physics, Particle and Plasma Physics, Positrons, Physics::Atomic and Molecular Clusters, Nuclear, Physics::Atomic Physics, Silicon Vertex Detector, Detectors and Experimental Techniques, Antihydrogen, Microwaves, Instrumentation, Physics, Condensed Matter::Quantum Gases, Neutral atom trap, Energetic neutral atom, Molecular, Fermion, Nuclear & Particles Physics, Other Physical Sciences, Antiproton, Antimatter, Atomic physics, Astronomical and Space Sciences, Lepton

Abstract

The ALPHA collaboration, based at CERN, has recently succeeded in confining cold antihydrogen atoms in a magnetic minimum neutral atom trap and has performed the first study of a resonant transition of the anti-atoms. The ALPHA apparatus will be described herein, with emphasis on the structural aspects, diagnostic methods and techniques that have enabled antihydrogen trapping and experimentation to be achieved. © 2013 Elsevier B.V.

28. First attempts at antihydrogen trapping in ALPHA

Author

G. B. Andresen, W. Bertsche, P. D. Bowe, C. C. Bray, E. Butler, C. L. Cesar, S. Chapman, M. Charlton, J. Fajans, M. C. Fujiwara, R. Funakoshi, D. R. Gill, J. S. Hangst, W. N. Hardy, R. S. Hayano, M. E. Hayden, A. J. Humphries, R. Hydomako, M. J. Jenkins, L. V. Jo̸rgensen, L. Kurchaninov, R. Lambo, N. Madsen, P. Nolan, K. Olchanski, A. Olin, R. D. Page, A. Povilus, P. Pusa, F. Robicheaux, E. Sarid, S. Seif El Nasr, D. M. Silveira, J. W. Storey, R. I. Thompson, D. P. van der Werf, J. S. Wurtele, Y. Yamazaki, Yasuyuki Kanai, and Yasunori Yamazaki

Subjects

Condensed Matter::Quantum Gases, Trap (computing), Physics, Energetic neutral atom, Magnetic trap, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Trapping, Superconducting magnet, Atomic physics, Penning trap, Antihydrogen, Magnetic field

Abstract

The ALPHA apparatus is designed to produce and trap antihydrogen atoms. The de- vice comprises a multifunction Penning trap and a superconducting, neutral atom trap having a minimum-B configuration. The atom trap features an octupole magnet for transverse confinement and solenoidal mirror coils for longitudinal confinement. The magnetic trap employs a fast shut- down system to maximize the probability of detecting the annihilation of released antihydrogen. In this article we describe the first attempts to observe antihydrogen trapping.