Estimating the γ-summing detector HECTOR efficiency using Geant4

Orlando Gomez; Craig Riengold; Anna Simon; Jack Wurzer; Joseph Arroyo; Matthew J Chamberlain; Farheen Naqvi; Artemis Spyrou; Alex C Dombos; Alicia Palmisano; Mallory K K Smith; Tyler Anderson; Adam M Clark; Drew T. Blankstein; Bryce Frentz; Matthew Hall; Samuel L Henderson; Xuyang Li; Shane Moylan; Patrick D O'Malley; Christopher J Seymour; Michael A Skulski Jr; Sabrina Y Strauss; Bryant J Vande Kolk; Wanpeng Tan

Estimating the γ-summing detector HECTOR efficiency using Geant4

ORAL

Abstract

The High Efficiency Total Absorption Spectrometer (HECTOR) is a NaI(Tl) 4π summing detector designed to measure radiative capture cross sections relevant for astrophysical processes. In a radiative capture, an excited compound nucleus de-excites via a series of gamma rays which are absorbed by the detector's scintillating array. In order to extract the cross section, the summing efficiency of the detector needs to be well understood. To determine efficiency, experimental yields are typically compared to Geant4 simulations if the level scheme and gamma-branching ratios are known. However, this technique proves to be particularly challenging for heavy nuclei, for which these quantities are not well known.

We present a statistical approach in which we correlate the efficiency with the average number of segments fired in an event “multiplicity” and the total energy of the gamma cascade. Gamma cascades of 100 branching ratios are generated from a uniform distribution and are then simulated using Geant4 to determine the efficiency. As a benchmark of the procedure, the spectroscopic factors of resonances in ²⁷Al(p,γ)²⁸Si measured recently with HECTOR will also be presented.

^*This work is supported by the NSF under grants: PHY-1614442, PHY-1713857 (NSL) and PHY-1430152 (JINA-CEE)

Oct. 27, 2018, 9:45 AM – Oct. 27, 2018, 10:00 AM

Presenters

Orlando Gomez
- University of Notre Dame
- Univ of Notre Dame

Authors

Orlando Gomez
- University of Notre Dame
- Univ of Notre Dame
Craig Riengold
- Univ of Notre Dame
Anna Simon
- Univ of Notre Dame
- University of Notre Dame
Jack Wurzer
- Univ of Notre Dame
Joseph Arroyo
- Univ of Notre Dame
Matthew J Chamberlain
- Univ of Notre Dame
Farheen Naqvi
- Univ of Notre Dame
- Yale University
- Yale Univ
- National Superconducting Cyclotron Laboratory
- Michigan State University
Artemis Spyrou
- National Superconducting Cyclotron Laboratory, Michigan State University
- National Superconducting Cyclotron Laboratory (NSCL)
- Michigan State Univ
- Michigan State Univ, National Superconducting Cyclotron
- Michigan State University
- National Superconducting Cyclotron Laboratory
Alex C Dombos
- National Superconducting Cyclotron Laboratory, Michigan State University
- Michigan State Univ
- National Superconducting Cyclotron Laboratory
Alicia Palmisano
- National Superconducting Cyclotron Laboratory, Michigan State University
- Michigan State Univ
- Michigan State University
Mallory K K Smith
- National Superconducting Cyclotron Laboratory, Michigan State University
- Michigan State University
- Michigan State Univ
- National Superconducting Cyclotron Laboratory
Tyler Anderson
- University of Notre Dame
- Univ of Notre Dame
Adam M Clark
- University of Notre Dame
- Univ of Notre Dame
Drew T. Blankstein
- Univ of Notre Dame
Bryce Frentz
- Univ of Notre Dame
- Department of Physics, University of Notre Dame, Notre Dame, IN, 46556
Matthew Hall
- Univ of Notre Dame
- University of Notre Dame
Samuel L Henderson
- Univ of Notre Dame
Xuyang Li
- Univ of Notre Dame
Shane Moylan
- Univ of Notre Dame
Patrick D O'Malley
- Univ of Notre Dame
Christopher J Seymour
- Univ of Notre Dame
Michael A Skulski Jr
- University of Notre Dame
- Univ of Notre Dame
Sabrina Y Strauss
- Univ of Notre Dame
Bryant J Vande Kolk
- Univ of Notre Dame
Wanpeng Tan
- Univ of Notre Dame