Nuclear Physics and Atomic Energy 24 (2023) 388

Ядерна фізика та енергетика
Nuclear Physics and Atomic Energy

ISSN: 1818-331X (Print), 2074-0565 (Online)
Publisher: Institute for Nuclear Research of the National Academy of Sciences of Ukraine
Languages: Ukrainian, English
Periodicity: 4 times per year

Open access peer reviewed journal

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Nucl. Phys. At. Energy 2023, volume 24, issue 4, pages 388-394.
Section: Engineering and Methods of Experiment.
Received: 24.08.2023; Accepted: 22.11.2023; Published online: 28.12.2023.

Full text (en)
https://doi.org/10.15407/jnpae2023.04.388

Influence of dead layer on the response function of planar and coaxial Ge detector using Monte Carlo method

R. A. El-Tayebany^*, N. Shaaban

Nuclear and Radiological Safety Research Center, Egyptian Atomic Energy Authority, Cairo, Egypt

^*Corresponding author. E-mail address: rreltyebany@gmail.com

Abstract: Germanium crystals have a dead layer that causes a decrease in efficiency since the layer is not useful for detection but strongly attenuates photons. The thickness of this inactive layer is not well known due to the existence of a transition zone where photons are increasingly absorbed. Therefore, using data provided by manufacturers in the detector simulation model, some strong discrepancies appear by changing the dead layer. Investigations into the Ge detector response functions for gamma rays have been conducted using straightforward physical mechanisms implemented by Monte Carlo simulations. The detector response function feature's most probable interaction mechanisms are described. The Monte Carlo method is applied to simulate the calibration of a HPGe detector in order to determine the total inactive germanium layer thickness and the active volume that is needed in order to study the response function for both types of detectors. Results indicated a strong impact of dead layer variations on the response function of the simulated detectors.

Keywords: dead layer, MCNPX, coaxial Ge, planar Ge, detection efficiency, gamma-ray.

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