Your search keyword '"Petteri Pusa"' showing total 2 results

1. Electron Plasmas as a Diagnostic Tool for Hyperfine Spectroscopy of Antihydrogen

Author

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

Subjects

Physics, Physics::General Physics, Cyclotron, Cyclotron resonance, Magnetic confinement fusion, Plasma, Electron, law.invention, Physics::Plasma Physics, law, Atom, Physics::Atomic Physics, Atomic physics, Antihydrogen, Hyperfine structure

Abstract

Long term magnetic confinement of antihydrogen atoms has recently been demonstrated by the ALPHA collaboration at CERN, opening the door to a range of experimental possibilities. Of particular interest is a measurement of the antihydrogen spectrum. A precise comparison of the spectrum of antihydrogen with that of hydrogen would be an excellent test of CPT symmetry. One prime candidate for precision CPT tests is the ground-state hyperfine transition; measured in hydrogen to a precision of nearly one part in 1012. Effective execution of such an experiment with trapped antihydrogen requires precise knowledge of the magnetic environment. Here we present a solution that uses an electron plasma confined in the antihydrogen trapping region. The cyclotron resonance of the electron plasma is probed with microwaves at the cyclotron frequency and the subsequent heating of the electron plasma is measured through the plasma quadrupole mode frequency. Using this method, the minimum magnetic field of the neutral trap can be determined to within 4 parts in 104. This technique was used extensively in the recent demonstration of resonant interaction with the hyperfine levels of trapped antihydrogen atoms.

Published

2013

2. Antiparticle plasmas for antihydrogen trapping

Author

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

Subjects

Nuclear physics, Antiproton Decelerator, Physics, Antiparticle, Large Hadron Collider, Energetic neutral atom, Antiproton, Physics::Accelerator Physics, High Energy Physics::Experiment, Physics::Atomic Physics, Plasma, Antihydrogen, Non-neutral plasmas

Abstract

Over the last decades it has become routine to form beams of positrons and antiprotons and to use them to produce trapped samples of both species for a variety of purposes. Positrons can be captured efficiently, for instance using a buffer-gas system, and in such quantities to form dense, single component plasmas useful for antihydrogen formation. The latter is possible using developments of techniques for dynamically capturing and then cooling antiprotons ejected from the Antiproton Decelerator at CERN. The antiprotons can then be manipulated by cloud compression and evaporative cooling to form tailored plasmas. We will review recent advances that have allowed antihydrogen atoms to be confined for the first time in a shallow magnetic minimum neutral atom trap superimposed upon the region in which the antiparticles are held and mixed. A new mixing technique has been developed to help achieve this using autoresonant excitation of the centreofmass longitudinal motion of an antiproton cloud. This allows efficient antihydrogen formation without imparting excess energy to the antiprotons and helps enhance the probability of trapping the anti-atom.

Published

2012