Measuring the 15O(α, γ)19Ne reaction rate in Type I X-ray bursts using the GADGET II TPC

Tyler Wheeler; Alexander Adams; Tony Ahn; James M Allmond; Hector Alvarez-Pol; Arian Andalib; Evan Argo; Yassid Ayyad; Dan W Bardayan; Daniel Bazin; Tamas A Budner; Alan Chen; Kelly A Chipps; Barry S Davids; Joseph Dopfer; Moshe Friedman; Hans Fynbo; Robert Grzywacz; Jordi Jose; Johnson Liang; Ruchi Mahajan; Steven D Pain; David Perez-Loureiro; Emanuel Pollacco; Athanasios Psaltis; Saiprasad Ravishankar; Andrew Rogers; Logan Schaedig; Lijie Sun; Jason Surbrook; Lexanne Weghorn; Christopher L Wrede

Measuring the <sup>15</sup>O(α, γ)<sup>19</sup>Ne reaction rate in Type I X-ray bursts using the GADGET II TPC

ORAL

Abstract

A neutron star can accrete H/He-rich material from a low-mass stellar companion (e.g., a main sequence star or a red giant). This can lead to thermonuclear runaway, which manifests as a Type I X-ray burst in a space-based telescope. Sensitivity studies have shown that the ¹⁵O(α, γ)¹⁹Ne reaction is one of the most important reaction rate uncertainties affecting the modeling of the resulting light curve. This reaction is expected to be dominated by the 4.03 MeV resonance in ¹⁹Ne. This state has a well known lifetime, so only a finite value for the alpha-particle branching ratio is needed to determine the reaction rate. Previous measurements have shown that this state is populated in the decay sequence of ²⁰Mg. ²⁰Mg(βpα)¹⁵O events through the key ¹⁵O(α, γ)¹⁹Ne resonance yield a characteristic signature: the emission of a proton and alpha particle. To identify these coincidence events we have upgraded the GADGET Proton Detector into a time projection chamber to form the GADGET II detection system. GADGET II has been constructed, and is in the final testing phase before FRIB PAC approved experiment 21072. Additionally, machine learning will be leveraged in analysis by fine-tuning a pre-trained convolutional neural network to identify the proton-alpha events of interest.

^*This work was supported by the U.S. National Science Foundation under Grants No. PHY-1102511, PHY-1565546, PHY-1913554, and PHY-1811855, and the U.S. Department of Energy, Office of Science, under award No. DE-SC0016052.

Oct. 28, 2022, 8:42 AM – Oct. 28, 2022, 8:54 AM

Presenters

Tyler Wheeler
- Michigan State University

Authors

Tyler Wheeler
- Michigan State University
Alexander Adams
- Michigan State University
Tony Ahn
- IBS
- Center for Exotic Nuclear Studies (CENS)
James M Allmond
- Oak Ridge National Lab
Hector Alvarez-Pol
- University of Santiago de Compostela
Arian Andalib
- Michigan State University
Evan Argo
- argo@frib.msu.edu
Yassid Ayyad
- University of Santiago de Compostela
- IGFAE
- Universidade de Santiago de Compostela
Dan W Bardayan
- University of Notre Dame
Daniel Bazin
- Michigan State University
- NSCL Michigan State University
- FRIB
Tamas A Budner
- Michigan State University
Alan Chen
- McMaster Univ
- McMaster University
Kelly A Chipps
- ORNL
Barry S Davids
- TRIUMF
Joseph Dopfer
- Michigan State University
Moshe Friedman
- Hebrew University of Jerusalem
Hans Fynbo
- Aarhus University
Robert Grzywacz
- University of Tennessee
- University of Tennessee and Oak Ridge National Laboratory
Jordi Jose
- Institucion de Estudios Complutenses
Johnson Liang
- TRIUMF
- McMaster Univ
- McMaster University
Ruchi Mahajan
- Facility for Rare Isotope Beams
Steven D Pain
- ORNL
David Perez-Loureiro
- National Superconducting Cyclotron Laboratory
- Canadian Nuclear Laboratories
Emanuel Pollacco
- CEA, France
- University of Paris-Saclay
- IRFU, CEA Saclay
Athanasios Psaltis
- TU Darmstadt
- Technical University of Darmstadt
Saiprasad Ravishankar
- Michigan State University
Andrew Rogers
- University of Massachusetts Lowell
- University of Massachusetts-Lowell
Logan Schaedig
- Michigan State University
Lijie Sun
- Shanghai Jiao Tong university
Jason Surbrook
- Michigan State University
Lexanne Weghorn
- Michigan State University
Christopher L Wrede
- Michigan State University