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Stacking Multiple Ion Captures in The High Performance Antiproton Trap (HiPAT)The High performance Antiproton Trap (HiPAT) research project was initiated by the Marshall Space Flight Center's propulsion Research Center to examining the fundamental behavior of low energy antiprotons. Stored antiproton would ultimately be used for experimental demonstration of basic propulsive concepts. Matter-antimatter annihilation produces approximately 10(exp 8) MJ/g nearly 10 orders of magnitude more energy per unit mass than chemical based combustion, hence NASA's interest. To achieve containment, HiPAT utilizes a type of electromagnetic bottle know as a Penning trap positioned within an ultrahigh vacuum test section. Recently, the HiPAT hardware configuration has been enhanced to facilitate the capture of multiple normal matter ion burst. This endeavor is often referred to as "stacking" and used to increasing the number of captured particles. A prior normal matter experimental effort, successfully demonstrated the effectiveness of single burst capture. The stacking process is accomplished by manipulating the electric field generated by the confinement electrodes i.e. adjusting the well potential depth. These potential well values are initially configured to maximize the quantity of captured ions per burst; shallow wells with a depth of 100 volt or less (referenced to the incoming ion beam energy) are typically selected. Once captured, a cooling interval is required to reduce the energy of trapped particles below the lower extent of the "trap door" (or leading electrode) ion emitting potential. This is necessary such that a new burst of hot ions can be introduced while preventing those already inside from escaping. The cooling time is driven by a combination of mechanisms such as synchrotron radiation, background gas scattering, and resistive damping in a time scale on the order of minutes. A potential for reducing this hold period is to actively manipulate the electric field shape, using the power supply control system, to produce a deeper potential well. The trapped ions ride down the morphing well to a lower potential energy, leaving margin to once again cycle the "trap door" capturing a new burst while limiting the number of escaping ions. By adjusting the magnitude and timing of the potential well shaping, subsequent shots from the ion beam can be captured on a time scale shorter then that dictated by the standard inject, capture and cool technique. Currently, experimental tests are under way examining the functionally of this system for stacking multiple ions bursts within the HiPAT system.
Document ID
20040040113
Acquisition Source
Marshall Space Flight Center
Document Type
Conference Paper
Authors
Martin, James J.
(NASA Marshall Space Flight Center Huntsville, AL, United States)
Lewis, Raymond A.
(NASA Marshall Space Flight Center Huntsville, AL, United States)
Sims, William H.
(NASA Marshall Space Flight Center Huntsville, AL, United States)
Chakrabarti, Suman
(NASA Marshall Space Flight Center Huntsville, AL, United States)
Pearson, Boise
(NASA Marshall Space Flight Center Huntsville, AL, United States)
Fant, Wallace E.
(NASA Marshall Space Flight Center Huntsville, AL, United States)
Date Acquired
August 21, 2013
Publication Date
January 1, 2004
Subject Category
Nuclear Physics
Meeting Information
Meeting: STAIF 2004 Conference
Location: Albuquerque, NM
Country: United States
Start Date: February 8, 2004
End Date: February 12, 2004
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.

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