Design and construction of a novel energy-loss optical scintillation system (ELOSS) for heavy-ion particle identification

We present the development of a novel heavy-ion particle-identification (PID) device based on an energy-loss measurement to be implemented in the focal plane of the S800 spectrograph of the Facility for Rare Isotope Beams (FRIB). The new instrument consists of a multi-segmented optical detector [energy-loss optical scintillation system (ELOSS)] that is filled with xenon at pressures ranging from 400 to 800 Torr. The gas volume is surrounded by arrays of photomultiplier tubes and placed along the direction of the beam for recording the prompt scintillation light. The number of detected photons, which is proportional to the energy deposited by the beam particle along its track in the detector volume, allows one to identify the corresponding atomic number (Z). The ELOSS technology is expected to provide high resolution AE measurements (<= 0.6% a) at a high counting rate (> 50 kHz). In addition, it has the capability of providing timing information with around 150 ps resolution (a) compared to the lack of useable timing information of the conventional ionization chamber relying on drifting charges. The development of fast, accurate AE measurement techniques for present and future nuclear science facilities will have a high impact on the design and implementation of rare-isotope beam experiments at FRIB and their scientific outcome. As such, ELOSS also represents a prototype for the development of PID detector systems of other planned and future spectrometers, such as the high rigidity spectrometer at FRIB.

Automated summary

This article presents the development of a novel heavy-ion particle-identification (PID) device based on energy-loss measurement to be used in the S800 spectrograph at the FRIB facility. The new instrument, called ELOSS, consists of a segmented optical detector filled with xenon, surrounded by photomultiplier tubes. It is expected to provide high-resolution AE measurements and timing information, which will have a significant impact on the design and implementation of rare-isotope beam experiments.