The 17F(α, p)20Ne Reaction Rate in Type 1 X-Ray Bursts from the Inverse Reaction
ORAL
Abstract
The 17F(α, p)20Ne reaction has been identified as an alternate pathway for
breakout from the hot-CNO cycle that can be important in some X-ray burst
scenarios. We have measured the 20Ne(p, α)17F cross section at low energies
ranging from 4.80 to 7.60 MeV using a proton beam on a neon gas cell with an
activation method and NaI detectors at the Fox Accelerator Laboratory at
Florida State University. Later, we measured the same reaction through
inverse kinematics with a 20Ne beam on a methylene target at the ATLAS
facility at Argonne National Laboratory. We used an annular Si strip detector for alpha
detection with recoiling heavy ions detected in the Enge spectrograph by the
MONICA focal plane detector. Studying the inverse kinematics reaction
allows us to distinguish alpha particles being emitted either to the ground or
first excited state of 17F. Cross sections will be compared to previous work,
and preliminary results from an R-matrix analysis constraining properties of
states in 21Na will be presented.
breakout from the hot-CNO cycle that can be important in some X-ray burst
scenarios. We have measured the 20Ne(p, α)17F cross section at low energies
ranging from 4.80 to 7.60 MeV using a proton beam on a neon gas cell with an
activation method and NaI detectors at the Fox Accelerator Laboratory at
Florida State University. Later, we measured the same reaction through
inverse kinematics with a 20Ne beam on a methylene target at the ATLAS
facility at Argonne National Laboratory. We used an annular Si strip detector for alpha
detection with recoiling heavy ions detected in the Enge spectrograph by the
MONICA focal plane detector. Studying the inverse kinematics reaction
allows us to distinguish alpha particles being emitted either to the ground or
first excited state of 17F. Cross sections will be compared to previous work,
and preliminary results from an R-matrix analysis constraining properties of
states in 21Na will be presented.
*Work supported by U.S. Dept of Energy via Award DE-FG02-96ER40978This research used resources of ANL’s ATLAS facility, which is a DOE Officeof Science User Facility
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Presenters
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William D Braverman
- Louisiana State University
- LSU