Identification of heavy isotope beams with multiple charge states

ORAL  · Invited

Abstract

One of the primary challenges in performing successful inverse-kinematics measurements with heavy nuclei is the successful identification and tagging of the beam, which often contains many species. For this purpose, the Heavy Isotope Tagger (HEIST) was developed and commissioned at the National Superconducting Cyclotron Laboratory (NSCL). HEIST utilizes two micro-channel plate timing detectors to measure the time-of-flight, a multi-sampling ion chamber to measure energy loss, and a high-purity germanium detector to identify isomer decays and calibrate the isotope identification system. We discuss the simulation and performance of HEIST using a rare isotope beam centered around 197Pb at about 75 MeV/A. With heavy nuclei at this energy, the beam is not fully stripped, and multiple charge states of each isotope can be present. This is one of the largest sources of contamination when trying to uniquely identify the beam. In this talk, we examine the simulation of beam production, including charge state distributions, and compare the simulation to the experimentally determined performance of HEIST. We will present the purity of typical experimental cuts on the beam PID and show how our measured charge state distributions compare to charge state models such as GLOBAL.

*We would like to acknowledge support from Michigan State University, from the U.S Department of Energy under Grant Nos. DE-SC0020451, DE-SC0014552, and DE-NA0003908, from the National Science Foundation under Grant Nos. PHY-1565546, and PHY-1712832.

Publication: Beam particle identification and tagging of incompletely stripped heavy beams with HEIST DOI: 10.1063/5.0068180

Presenters

  • Adam K Anthony

    • Michigan State University

Authors

  • Adam K Anthony

    • Michigan State University

  • Chenyang Niu

    • Michigan State University

  • Rensheng Wang

    • National Superconducting Cyclotron Labor

  • Joseph M Wieske

    • Michigan State University

  • Zbigniew Chajecki

    • Western Michigan University

  • William G Lynch

    • Michigan State University

  • Francesc Yasid Ayyad Limonge

    • Michigan State University

  • Jonathan Barney

    • Los Alamos National Laboratory
    • Michigan State University

  • Thomas Baumann

    • FRIB/NSCL
    • Facility for Rare Isotope Beams

  • Daniel Bazin

    • Michigan State University

  • Saul Beceiro-Novo

    • Michigan State University

  • Jie Chen

    • Argonne National Laboratory

  • Kaitlin J Cook

    • Michigan State University

  • Marco Cortesi

    • NSCL Cyclotron Lab

  • Tom N Ginter

    • FRIB/NSCL
    • FRIB

  • Wolfgang Mittig

    • Facility for Rare Isotope Beams, Michigan State University, East Lansing, MI
    • Michigan State University

  • Andrew Pype

    • Michigan State University

  • Mallory K Smith

    • Facility for Rare Isotope Beams
    • FRIB
    • Michigan State University

  • Chandana S Sumithrarachchi

    • Michigan State University
    • Facility for Rare Isotope Beams
    • MSU
    • FRIB/NSCL

  • Sean R Sweany

    • Michigan State University

  • Chi-En Teh

    • National Superconducting Cyclotron Laboratory, MSU
    • Facility for Rare Isotope Beams, MSU

  • Chun Yuen Tsang

    • Kent State University

  • Betty Tsang

    • Michigan State University
    • FRIB

  • Nathan Watwood

    • Michigan State University

  • Alan H Wuosmaa

    • University of Connecticut