Utilizing machine learning for fast-timing calibration between LaBr3(Ce) detectors in the neutron-rich N = 20 and N=50 regions

Tawfik M Gaballah; Benjamin P Crider; Sean N Liddick; Sean P Burcher; Michael P Carpenter; James J Carroll; Aaron Chester; Christopher J Chiara; Kathrine Childers; Partha Chowdhury; Patrick A Copp; Jason T Harke; Daniel E Hoff; Kay Kolos; Edward Lamere; Rebecca Lewis; Brenden R Longfellow; Stephanie Lyons; Mejdi J Mogannam; Shree K Neupane; Timilehin H Ogunbeku; David Perez-Loureiro; Christopher J Prokop; Daniel M Rhodes; Andrea Richard; Olalekan A Shehu; Durga P Siwakoti; Dylan C Smith; Mallory K Smith; Aaron S Tamashiro; Ronald Unz; Yongchi Xiao

Utilizing machine learning for fast-timing calibration between LaBr3(Ce) detectors in the neutron-rich N = 20 and N=50 regions

ORAL

Abstract

The nuclear shell evolution can be attributed to changing proton and neutron numbers within the nucleus. Nuclear transition rates, which significantly depend on a precise measurement of level lifetimes, are sensitive indicators for investigating the nuclear shell evolution. Experiments using β decay in the neutron-rich N=20 and N=50 regions were performed at the National Superconducting Cyclotron Laboratory (NSCL). β decays were correlated with the implantation of radioactive nuclei, using a CeBr3 scintillator coupled to a Position-Sensitive Photomultiplier Tube (PSMPT), through spatial and temporal analysis techniques. In these experiments, 15 LaBr3(Ce) detectors were employed for γ radiation detection and fast timing measurement. Time-difference spectra between β decays and γ radiation detection were used to measure half-lives. Calibration of the LaBr3 timing response relative to the CeBr3 was performed along with further corrections for the energy dependent time-walk effects were made using machine learning techniques in the neutron-rich N=20 and N=50 regions. Validation results from comparing the output from the machine learning model with the output from the analytical technique used in previous analysis will be presented.

Nov. 28, 2023, 9:15 PM – Nov. 28, 2023, 9:30 PM

Presenters

Tawfik M Gaballah
- Mississippi State University

Authors

Tawfik M Gaballah
- Mississippi State University
Benjamin P Crider
- University of Kentucky
- Mississippi State University
Sean N Liddick
- Michigan State University
- FRIB
- FRIB/NSCL
- Facility for Rare Isotope Beams, Michigan State University, East Lansing, MI 48824, USA
- FRIB/MSU
Sean P Burcher
- Lawrence Livermore Natl Lab
Michael P Carpenter
- Argonne National Laboratory
James J Carroll
- US Army Research Lab Adelphi
Aaron Chester
- Michigan State University
Christopher J Chiara
- US Army Research Lab Adelphi
Kathrine Childers
- FRIB
- Michigan State University
Partha Chowdhury
- University of Massachusetts Lowell
Patrick A Copp
- Argonne National Laboratory
Jason T Harke
- Lawrence Livermore Natl Lab
Daniel E Hoff
- Lawrence Livermore National Laboratory
Kay Kolos
- LLNL
Edward Lamere
- University of Massachusetts Lowell
Rebecca Lewis
- Michigan State University
Brenden R Longfellow
- Lawrence Livermore National Laboratory
Stephanie Lyons
- Michigan State University
Mejdi J Mogannam
- Michigan State University
Shree K Neupane
- University of Tennessee
Timilehin H Ogunbeku
- FRIB
- Facility for Rare Isotope Beams
- Mississippi State University
David Perez-Loureiro
- University of Tennessee, Knoxville
Christopher J Prokop
- Los Alamos National Laboratory
Daniel M Rhodes
- Michigan State University
Andrea Richard
- Facility for Rare Isotope Beams
Olalekan A Shehu
- Mississippi State University
Durga P Siwakoti
- Mississippi State Univ
Dylan C Smith
- Mississippi State University
Mallory K Smith
- NSCL
- Michigan State University
Aaron S Tamashiro
- Oregon State University
Ronald Unz
- Mississippi State University
Yongchi Xiao
- University of Kentucky
- Mississippi State University