Experimental Investigation of the Ne 19 (p,γ)20Na Reaction Rate and Implications for Breakout from the Hot CNO Cycle

Authors

J. Belarge, Florida State University
S. A. Kuvin, Florida State University
L. T. Baby, Florida State University
J. Baker, Florida State University
I. Wiedenhöver, Florida State University
P. Höflich, Florida State University
A. Volya, Florida State University
J. C. Blackmon, Louisiana State University
C. M. Deibel, Louisiana State University
H. E. Gardiner, Louisiana State University
J. Lai, Louisiana State University
L. E. Linhardt, Louisiana State University
K. T. Macon, Louisiana State University
E. Need, Louisiana State University
B. C. Rasco, Louisiana State University
N. Quails, University of North Florida
K. Colbert, University of North Florida
D. L. Gay, University of North FloridaFollow
N. Keeley, Narodowe Centrum Badań Jądrowych, Otwock

Document Type

Article

Publication Date

10-27-2016

Abstract

The Ne19(p,γ)Na20 reaction is the second step of a reaction chain which breaks out from the hot CNO cycle, following the O15(α,γ)Ne19 reaction at the onset of x-ray burst events. We investigate the spectrum of the lowest proton-unbound states in Na20 in an effort to resolve contradictions in spin-parity assignments and extract reliable information about the thermal reaction rate. The proton-transfer reaction Ne19(d,n)Na20 is measured with a beam of the radioactive isotope Ne19 at an energy around the Coulomb barrier and in inverse kinematics. We observe three proton resonances with the Ne19 ground state, at 0.44, 0.66, and 0.82 MeV c.m. energies, which are assigned 3+, 1+, and (0+), respectively. In addition, we identify two resonances with the first excited state in Ne19, one at 0.20 MeV and one, tentatively, at 0.54 MeV. These observations allow us for the first time to experimentally quantify the astrophysical reaction rate on an excited nuclear state. Our experiment shows an efficient path for thermal proton capture in Ne19(p,γ)Na20, which proceeds through ground state and excited-state capture in almost equal parts and eliminates the possibility for this reaction to create a bottleneck in the breakout from the hot CNO cycle.

Publication Title

Physical Review Letters

Volume

117

Issue

18

Digital Object Identifier (DOI)

10.1103/PhysRevLett.117.182701

ISSN

00319007

E-ISSN

10797114

Citation Information

Belarge, Kuvin, S. A., Baby, L. T., Baker, J., Wiedenhöver, I., Höflich, P., Volya, A., Blackmon, J. C., Deibel, C. M., Gardiner, H. E., Lai, J., Linhardt, L. E., Macon, K. T., Need, E., Rasco, B. C., Quails, N., Colbert, K., Gay, D. L., & Keeley, N. (2016). Experimental Investigation of the Ne 19 ( p , γ ) 20 Na Reaction Rate and Implications for Breakout from the Hot CNO Cycle. Physical Review Letters, 117(18). https://doi.org/10.1103/PhysRevLett.117.182701