Abstract
We have proposed a planar electronically segmented high-purity germanium (HPGe) detector concept in combination with a multislit collimator for gamma emission tomography. In this work, the spatial resolution achievable using the collimated segmented HPGe detector was evaluated, prior to the manufacture and operation of the detector. The spatial response of a collimated segmented HPGe detector concept was evaluated using simulations performed with Monte Carlo N-Particle (MCNP) transport code MCNP6. The full detector and multislit collimator system were modeled, and for the quantification of the spatial response, the modulation transfer function (MTF) was chosen as a performance metric. The MTF curve was obtained through the calculation of the line spread function (LSF) by analyzing the simulated projection data. In addition, tomographic reconstructions of the simulated simplified test objects were made to demonstrate the performance of the segmented HPGe detector in planned application. For 662-keV photons, the spatial resolution obtained was approximately the same as the collimator slit width for both the 100- and 150-mm-long collimators. The corresponding spatial resolution at 1596-keV photon energy was almost twice the slit width for the 100-mm collimator, due to the partial penetration of the high-energy gamma rays through the collimator bulk. For a 150-mm-long collimator, an improved resolution was obtained.
Highlights
HPGE (HIGH PURITY GERMANIUM) detectors are well known for their excellent energy resolution and reasonably high detection efficiency in the gamma-ray spectrometry field
The spatial response of a collimated segmented HPGe detector was obtained from the simulation study using particle transport code MCNP6.2
The Line Spread Function (LSF) and the Modulation Transfer Function (MTF) were obtained for two different lengths of the multi-slit collimator
Summary
HPGE (HIGH PURITY GERMANIUM) detectors are well known for their excellent energy resolution and reasonably high detection efficiency in the gamma-ray spectrometry field. Because of these properties, HPGe detectors are widely used in many scientific applications. The GET technique has been used in the examination of nuclear fuel rods exposed to inpile transient tests in material test reactors [5,6,7]. In such GET inspections, high spatial resolution is valuable for studying fragmentation, relocation, and dispersal of fuel from a fuel element or rod. The feasibility of segmented HPGe detector for GET instruments was evaluated through the simulation study in [3], and the detector geometry and segmentation pattern were optimized in [4]
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