Abstract
During nuclear decommissioning or waste management operations, a camera that could make an image of the contamination field and identify and quantify the contaminants would be a great progress. Compton cameras have been proposed, but their limited efficiency for high energy gamma rays and their cost have severely limited their application. Our objective is to promote a Compton camera for the energy range (200 keV – 2 MeV) that uses fast scintillating crystals and a new concept for locating scintillation event: Temporal Imaging. Temporal Imaging uses monolithic plates of fast scintillators and measures photons time of arrival distribution in order to locate each gamma ray with a high precision in space (X,Y,Z), time (T) and energy (E). This provides a native estimation of the depth of interaction (Z) of every detected gamma ray. This also allows a time correction for the propagation time of scintillation photons inside the crystal, therefore resulting in excellent time resolution. The high temporal resolution of the system makes it possible to veto quite efficiently background by using narrow time coincidence (< 300 ps). It is also possible to reconstruct the direction of propagation of the photons inside the detector using timing constraints. The sensitivity of our system is better than 1 nSv/h in a 60 s acquisition with a 22Na source. The project TEMPORAL is funded by the ANDRA/PAI under the grant No. RTSCNADAA160019.
Highlights
THE concept of Compton camera was first investigated to detect gamma rays within the energy range 150 keV – 511 keV in the medical field [1]
We propose here a new concept called Temporal Imaging to build a Compton camera based on fast monolithic scintillation crystals
The energy resolution obtained is quite good for large monolithic plates (11.0% FWHM with LYSO and 6.9 % FWHM with CeBr3 at 511 keV)
Summary
Mostly by using semiconductors like CdTe or CZT. such detectors are limited by their small active size, detection efficiency and high background noise level. We propose here a new concept called Temporal Imaging to build a Compton camera based on fast monolithic scintillation crystals. In this concept in addition to light sharing, we use, photon time of flight within the scintillation crystal to accurately calculate the location of every gamma ray event. This acquisition concept allows a good positioning resolution, within the plane of detection (∆X, ∆Y < 2 mm FWHM), and a good estimation of the depth of interaction (DOI) (∆Z < 2 mm FWHM). We present some results and images obtained using our LYSO demonstrator
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