Evaluation of a simple method for chopping Penning surface‐plasma source H− beams

Accumulator rings proposed for use in high‐intensity spallation‐neutron sources require a chopped beam with ∼100‐ns‐wide particle‐free gaps at 1–2 MHz rates, with fall and rise times ≤20 ns. Chopping the beam directly in the ion source may be an attractive way to provide the desired beam structure....

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Bibliographic Details
Published in:Review of scientific instruments 1995-02, Vol.66 (2), p.1024-1027
Main Authors: Smith, H. Vernon, Allison, Paul, Schneider, J. David, Stelzer, James E., Stevens, Ralph R.
Format: Article
Language:English
Subjects:
ANIONS
BEAM CURRENTS
BEAM INJECTION
BEAM PULSERS
BEAM SHAPING
CHARGED PARTICLES
CURRENTS
HYDROGEN IONS
HYDROGEN IONS 1 MINUS
ION BEAM INJECTION
ION SOURCES
IONS
PARTICLE ACCELERATORS
PENNING ION SOURCES
PULSE RISE TIME
TIMING PROPERTIES 430301 > Particle Accelerators-- Ion Sources
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Summary:Accumulator rings proposed for use in high‐intensity spallation‐neutron sources require a chopped beam with ∼100‐ns‐wide particle‐free gaps at 1–2 MHz rates, with fall and rise times ≤20 ns. Chopping the beam directly in the ion source may be an attractive way to provide the desired beam structure. Previous measurements showed that placing a grounded collar in the drift region just before the emission aperture lowers the e −/H− ratio in the Penning surface‐plasma source H− beam. We electrically isolated the collar and biased it to modulate the extracted H− current. Positive collar bias decreases the H− beam by up to 90%. The fastest H− current fall and rise times achieved to date are 400 ns and 2 μs, respectively. The current fall time is close to the 300‐ns pulser rise time. The current rise time is considerably longer than the 500‐ns pulser fall time. Negative collar bias lowers the H− beam by up to 50%. Simulations indicate that the beam time structure will be preserved in transport from the ion source to the radio‐frequency quadrupole entrance.
ISSN:0034-6748
1089-7623
DOI:10.1063/1.1146039